58

TH TH ANNUAL CONFERENCE ON MAGNETISM AND MAGNETIC MATERIALS 58 ANNUAL CONFERENCE ON MAGNETISM AND MAGNETIC MATERIALS 4–8 November 2013 Denver, Colorado

www.magnetism.org PROGRAM 1

General Information

SCOPE OF THE CONFERENCE The 58th Magnetism and Magnetic Materials Conference is sponsored joint- ly by AIP Publishing, LLC (AIPP) and the Magnetics Society of the IEEE, in cooperation with the American Physical Society. Members of the interna- tional scientific and engineering communities interested in recent develop- ments in fundamental and applied magnetism are invited to attend the Con- ference and contribute to its technical sessions. Sessions will include invited and contributed papers, oral and poster presentations, and invited symposia. This Conference provides an outstanding opportunity for world-wide partic- ipants to meet their colleagues and collaborators and discuss developments in all areas of magnetism research. In terms of the number of presentations, this will be one of the largest MMM in the history of the Conference, with close to 1700 oral and poster presentations.

DENVER, COLORADO The City of Denver is the Capitol of the State of Colorado, and has an ele- vation of exactly one mile above sea level. Denver also claims to brew more beer than any other city in the United States. The average daytime tempera- ture in early November is a high of 45 degrees Fahrenheit; the nighttime low is 25 degrees Fahrenheit. The week of the MMM 2013 Conference is also “Denver Arts Week” dur- ing which six of Denver’s vibrant art districts will be transformed into a fes- tival atmosphere with more than 300 events located in Denver’s intimate galleries and theaters, landmark museums and one-of-a-kind performing arts venues. The Starz Denver Film Festival on November 6th-9th will showcase hundreds of documentaries, shorts and other silver screen gems. Heavily discounted or free events are available during Denver Arts Week, allowing visitors to seamlessly access the full spectrum of what Colorado’s lively culture has to offer. Full information can be found at the Denver Arts Week website: http://www.denver.org/denverartsweek.

SPECIAL CONFERENCE EVENTS Monday Tutorial On Monday, November 4th, in the afternoon from 2:00-5:30 PM there will be a Tutorial on “Berry Phases in Magnetism” (session XA) in Plaza Ball- room BC on the Concourse Level of the Plaza Building of the Sheraton Denver Downtown Hotel. Three speakers (Jairo Sinova, Karin Everschor- Sitte, and Yoshinori Onose) will present various aspects about how ideas related to Berry phases can be used to understand phenomena in magnetism ranging from Hall effects, skyrmions, multiferroics and other complex mag- netic ordering and dynamic phenomena. Registration will open at 1:00 PM in the Ballroom Foyer close to the Tutorial location. Monday Evening Opening Reception On Monday evening there will be a Welcome and Networking Reception held from 6:00 PM until 10:00 PM at “Katie Mullen’s Irish Pub” adjacent to the Sheraton Denver Downtown Hotel. Beer, wine, soft drinks, and hors d’oeuvres will be served, generously sponsored by the IEEE Magnetics Society. Furthermore, live music entertainment will be provided by the Physics Rock and Roll Orchestra of the University of Colorado, Colorado Springs. Participants are required to present a conference badge to attend and the Registration Desks at the hotel will remain open until the early evening. Plan to be there! 2 3

Special Evening Talks: Tuesday and Thursday All 2013 MMM Conference attendees, including invited speakers, must There will be special evening talks in Plaza Ballroom BC on the Concourse pay registration fees. Level of the Plaza Building of the Sheraton Denver Downtown Hotel from REMEMBER: All “Advance Registration” forms must be accompa- 6:00-7:00 PM on both Tuesday, November 5th, and Thursday, November nied by FULL payment and must be received by October 11, 2013. 7th. On Tuesday, John Kitching (NIST) will show how optical atomic mag- Onsite registration during the Conference will be at the higher rates listed netometer can be used for extremely high precision measurements for a below. After October 11th, only the higher registration fees will be accept- variety of applications (talk YA-01). On Thursday, Nobel Laureate Albert ed, and only at the Onsite Registration Desks at the Conference. Forms not Fert (CNRS/Thales) will talk about his perspectives on how spin-orbit inter- accompanied by payment or with incomplete or incorrect credit card actions can be utilized in novel spintronic applications (talk ZA-01). information will be considered late and the higher rates will be collect- Bierstubes and Coffee ed onsite at the Conference. Complimentary coffee service will be available on Tuesday through Friday PLEASE NOTE: This MMM Conference begins on Monday, Novem- mornings in the Plaza Ballroom Foyer, along with the Exhibits and Poster ber 4th, with the Tutorial and a “Welcome and Networking Reception.” Sessions, from 9:00 AM–11:00 AM. On Tuesday through Thursday The Registration Desks will open from 1:00 PM-8:00 PM on Monday evenings, the Bierstube will be held from 4:30 PM–6:00 PM in this same so that you may register prior to both of these events. location. On Tuesday and Thursday evenings the Bierstubes will again be Registration Fees Prior to October 11th After October 11th sponsored through the generosity of Materion. Full Registrant $485.00 $585 Student Lunch with the Experts: Wednesday Student $240.00 $290 This event was introduced two years ago with great success, and so it is Unemployed/Retiree $240.00 $290 being continued. Students will have a chance to meet “Experts” from indus- The registration fees do not include any full meals or meal service during the try, universities and national laboratories over lunch (provided by the Con- Conference week. ference) on Wednesday November 6th at 12:30 -1:30 PM. It will be held at Registration Cancellation Policy: Cancellations of advance registrations “Katie Mullen’s Irish Pub” located adjacent to the conference hotel. In early must be submitted in writing and received no later than Friday, October October, the speakers and topics will be announced in an email that will be 11 2013. Refunds of the original payment, less a $75 service fee, will be sent, along with a registration form just for this event, to paid student regis- mailed to the original registrant following the Conference. Substitutions trants. Interested students will have to complete the registration form and may be made at any time, both on the Registration website and at the return it to [email protected]. Attendance will be limited. This onsite registration desk, for a registrant who cannot attend but has paid the is an excellent opportunity to explore career opportunities or just find out registration fee in advance. Onsite substitutes must bring authorization in more about life as a professional scientist or engineer. writing from the original registrant. There is no charge for substitutions. Women in Magnetism Networking Event The IEEE Magnetics Society will be sponsoring a Networking Reception REGISTRATION HOURS for women in the magnetism community on Thursday, November 7th, The Conference Registration Desks, located in the Plaza Ballroom Foyer beginning at 5:00 PM in Director’s Row H located on the Lobby Level of one level below the hotel’s Lobby, will be open during the following hours: the Plaza Building of the hotel. This is an opportunity to become acquaint- ed with other women in the profession and to discuss a range of topics Monday, November 4th 1:00 PM – 8:00 PM including leadership, work-life balance, and professional development. At Tuesday, November 5th 7:00 AM – 4:30 PM the reception you will also have the opportunity to form small dinner groups Wednesday, November 6th 8:00 AM – 4:30 PM in order to build new friendships and expand your professional network. All Thursday, November 7th 8:00 AM – 4:30 PM graduate students, researchers and retirees are encouraged to attend. If you have questions, please contact Pallavi Dhagat ([email protected] PLEASE NOTE: The Registration Desks will not be open on Friday, state.edu) or Julie Borchers ([email protected]). November 8th. If you need registration assistance on Friday please go to NIST Reunion Reception the Conference Office. NIST employees, alumni, associates, collaborators and friends are invited to Badge Policy: All attendees will be required to wear 2013 MMM Con- attend a reception on Thursday from 5:00 until 6:00 p.m. in Governors ference name badges to enter the Technical Sessions, Exhibits and the Square 10, located on the Concourse Level of the Plaza Building of the Welcome Reception. hotel. For questions, contact Ron Goldfarb ([email protected]) or Bob Recording Equipment Policy: The use of cameras, videotaping and/or Shull ([email protected]). recording devices in the technical sessions is strictly prohibited.

CONFERENCE REGISTRATION WIRELESS ACCESS You are encouraged to register via the secure web site at: Wireless access will be available throughout the Plaza Ballroom Foyer www.yesevents.com/mmm where the exhibits and poster sessions will also be located. An access code will be posted onsite. Casual seating will be spread throughout the area and If you prefer, you may also register by downloading and completely filling out in a few of the smallest rooms surrounding the foyer so that attendees can the Advance Registration Form obtained from yesevents on the registrations gather informally to network and access the Internet. Internet access will not site. Payment in U.S. dollars must be made by personal or corporate check be available in the oral session rooms. (drawn on a U.S. bank only), wire transfer or by MasterCard, Visa or Amer- ican Express credit card. Make checks payable to: “2013 MMM Conference.” 4 5

PUBLICATIONS Speaker Practice Room (Plaza Court 5) or in the assigned room for your talk before start of the session. There will be no technical support provided Conference proceedings will be published in a special issue of Journal of for the speaker-supplied equipment. To partially protect yourself Applied Physics scheduled to appear in print in April 2014. All manuscripts must against laptop failure, it is suggested that you also bring a copy of your be submitted online before the September 23, 2013 deadline using the AIP web presentation on a USB flash memory stick as a back-up. However, ses- submission system PeerX-Press (PXP). Guidelines for manuscript preparation sion timing must be maintained and therefore no additional presenta- may be found at the submission site (http://mmm.peerx-press.org). Review stan- tion time will be given in the event of technical difficulties. dards will mirror those used for regular articles submitted to Journal of Applied Physics. The Publications Room, where authors can check the status of their manu- POSTER SESSIONS scripts, will be located in Plaza Court 1 on the Ballroom Level of the hotel. The status of all papers can be found here and authors should check periodically on The Poster Sessions will be in the Plaze Exhibit Foyer and Plaza Balloom A their individual papers if they have questions. This room will be open as follows: and will be open from 9:30 AM–12:30 PM (morning poster sessions) and 2:30 PM–5:30 PM (afternoon poster session). Authors should set up their Monday, November 4th 6:00 PM – 7:00 PM materials at least 30 minutes before session start times. Poster presenters Tuesday, November 5th 8:00 AM – 5:00 PM MUST be present at their poster for the last hour of each Poster Session Wednesday, November 6th 9:00 AM – 5:00 PM (11:30 Noon-12:30 PM for morning sessions and 4:30 – 5:30 PM for Thursday, November 7th 9:00 AM – 5:00 PM afternoon sessions). Guidelines for preparation of Posters are found at: Friday, November 8th 9:00 AM – 12:00 Noon http://www.magnetism.org/presentation.html. Authors are reminded to remove all of their materials PROMPTLY at the end of their session SPEAKER PRACTICE ROOM (except the push-pins provided by the Conference). Any poster materi- als not removed may be discarded by Conference coordinators in order Speakers may use Plaza Court 5 on the Concourse Level of the Plaza to prepare for the next session. Building of the hotel to practice their presentations and test their computer connections with the in-house equipment prior to your individual presenta- tion. Audiovisual equipment (LCD projector and screen) will be available EXHIBITS for speakers to use from Monday at 1:00 PM until Friday at 1:00 PM. Speakers are encouraged to use this facility to practice their presentation, An exhibition of Magnetism-related services, equipment, materials, and software either alone or with colleagues. will be held as a part of the Conference. The exhibits will be located adjacent to the poster sessions in the Plaza Exhibit Foyer on the Concourse Level adjacent to the Plaza Ballroom. SESSION CHAIRS Confirmed exhibitors/supporters: Poster and Oral Session Chairs are expected to attend the Session Chair’s • AJA International Breakfast on the morning of the session that they are chairing. If you are • American Magnetics chairing an oral session, please be sure to bring your laptop computer • Attocube to the Conference or arrange to borrow one during your session, as the • Capres A/S Chair’s laptop will be used for session timing. Further details will be • Cryogenic Limited emailed to Session Chairs a few weeks before the conference. • GMW Associates • Hinds Instruments, Inc. • IOP Publishing ORAL SESSIONS • Kaufman and Robinson, Inc. • Lake Shore Cryotronics The oral sessions will be from 8:30–11:30 AM and 1:30–4:30 PM with the • LE USA Walker Scientific Inc. detailed order and locations of talks as listed in the program. Speakers are • Materion Microelectronics and Services reminded that the Conference requires an all-electronic oral presenta- • MicroSense,LLC tion format. Therefore, only video LCD projectors will be available for • MTI Corporation oral presentation materials. Authors are expected to bring their presentation • NanoScan AG on their own laptop computer, and have it powered on and ready to connect • Quantum Design to the projector. Only standard PC-style VGA connections to the LCD • Singulus Technologies projector will be supplied, therefore you must supply any required • SmartTip adaptor to your computer. In particular, Mac OS users must make • Tohoku Steel Co., Ltd. sure that they have the correct adaptor plug and that video “mirroring” • UBE Materials Industries, Ltd. is activated. • World Scientific Publishing In each session room, there will be a multi-port switchbox so that a speaker • Zurich Instruments can connect his/her laptop during the question period of the previous speak- For a complete up-to-date list of exhibitors please check at er. Each speaker will be solely responsible for promptly connecting to www.magnetism.org/exhibits.html, as well as the exhibits program available at the projector and switching to the correct input port. The presentation the conference. timer will begin immediately after the introduction by the Session Chair, and there is no extra time allotted to troubleshoot connections or reboot your computer. You are therefore STRONGLY ENCOURAGED to test your lap- top connections and screen resolution settings with the projectors in the 6 7

58th MMM CONFERENCE BEST STUDENT AV-05. Uniaxial magnetocrystalline anisotropy for hcp Co-Pt PRESENTATION FINALISTS disordered alloy films by reducing the stacking faults with adding third element based on valence electron engineering. Yanan Geng, AE-07, Direct visualization of magnetoelectric domains N. Nozawa1, S. Saito1, S. Hinata1 and M. Takahashi2 in hexagonal ErMnO3. 1. Department of Electronic Engineering, Tohoku University, Sendai, Nicholas Aimon, AE-08, Templated perovskite/spinel magnetoelectric Miyagi, Japan; 2. New Industry Creation Hatchery Center, Tohoku nanocomposites. University, Sendai, Miyagi, Japan Jean-Philippe Tetienne, BB-13, Real-space observation and laser control BQ-09. Probing depth-dependent magnetization reversal in of domain wall hopping in an ultrathin magnetic wire. nanoporous Co/Pt with polarized neutron reflectometry. Elizabeth Rapoport, BH-06, Programmable manipulation of superparamagnetic B.J. Kirby1, M.T. Rahman2,3, R.K. Dumas4,5, J.E. Davies6, P. Greene4, microbeads at junctions using magnetic domain walls. C.H. Lai2 and K. Liu4 Tianxiang Nan, CH-05, Self-Biased 215MHz Magnetoelectric NEMS 1. NIST Center for Neutron Research, National Institute of Standards and Resonator for Ultra-Sensitive DC Magnetic Field Detection. Technology, Gaithersburg, MD; 2. Materials Science and Engineering, National Tsing Hua University, Hsinchu, Taiwan; 3. MINT Center, Alan Farhan, DD-01, Direct observation of thermal relaxation University of Minnesota, Minneapolis, MN; 4. Physics, University of in artificial spin ice California at Davis, Davis, CA; 5. Physics, University of Gothenburg, Gothenburg, Sweden; 6. Advanced Technology Group, NVE Corporation, The student finalists for the 12th Joint MMM/Intermag Conference Eden Prarie, MN Best Student Presentation were: Azure Avery, Hiroshi Idzuchi, Xue Lin, Elizabeth Rapoport, and Uwe Bauer BU-06. High TMR ratio in Co2FeSi and Fe2CoSi based magnetic tunnel junctions. 1 1 1 1 1 The 12th Joint MMM/Intermag Conference C. Sterwerf , M. Meinert , J. Schmalhorst , M. Glas , G. Reiss 2 Best Student Presentation Winner and E. Arenholz 1. Bielefeld University, Thin Films and Physics of Nanostructures, Uwe Bauer, MIT Department of Physics, Bielefeld, Germany; 2. Lawrence Berkeley National Laboratory, Advanced Light Source, Berkeley, CA CONGRATULATIONS TO ALL!!! CP-05. Enhanced Gilbert damping at Permalloy/graphene interfaces. S. Singh1, A. Patra2, B. Barin1, E. del Barco1 and B. Ozyilmaz2 BEST POSTER PRESENTATIONS 1. Department of Physics, University of Central Florida, Orlando, FL; 2. Eligibility: All posters will be eligible for nomination for this award pro- Department of Physics, National University of Singapore, Singapore vided that they meet the requirements and guidelines for the 58th Annual CX-11. Thermal stability of the ferromagnetic in-plane uniaxial MMM Conference poster presentations and sessions, as described on the anisotropy of Fe-Co-Hf-N/Ti-N multilayer films for high-frequency website. The presentations should consist of well-prepared visual materials sensor applications. about the work, posted on a designated board. It is required that an author K. Krueger1, K. Seemann1, H. Leiste1, M. Stueber1, C. Thede2 be registered for the conference and in attendance to present details and and E. Quandt2 answer questions during a designated session time. In particular, they need 1. Institute for Applied Materials (IAM-AWP), Karlsruhe Institute of to be present during the 2 hours at the start of the Poster Session (9:30 AM Technology, Eggenstein-Leopoldshafen, Germany; 2. Institute for - 11:30 AM for morning sessions and 2:30 PM - 4:30 PM for afternoon Materials Science, Kiel University, Kiel, Germany sessions). Since the award will be made at the session, it is recommended that the authors be present for the majority of the session. All posters must DT-09. Anistropy Investigations in L10-Structured FeNi (Tetrataenite). include a full contact mailing address in the case that the authors are not 1 2 2 3 3 present when the award is made. N. Bordeaux , A. Mubarok , J.I. Goldstein , F.E. Pinkerton , E. Poirier and L.H. Lewis1 Nature of the Award: This award consists of a $50 certificate. The awards 1. Chemical Engineering, Northeastern University, Boston, MA; 2. will be made in the last hour of each poster session. A ribbon will also be Department of Mechanical and Industrial Engineering, University of attached to the successful posters. Winning posters will be prominently dis- Massachusetts, Amherst, MA; 3. Research and Development Center, played through the remainder of the conference. General Motors, Warren, MI Selection Process: A Poster Award Committee will review all of the posters DV-16. Structural, Magnetic and Magnetoelastic Properties of at the beginning of each session. Nominations will be made by the individ- Magnesium Substituted Cobalt Ferrite. ual session chairs which will be forwarded to the Award Committee. Selec- C.I. Nlebedim1,2, R.L. Hadimani2,1, R. Prozorov1,3 and D.C. Jiles2,1 tions will be based on the level of the research, quality of the poster, and 1. Ames Laboratory, US Department of Energy, Iowa State University, clarity of the presentation. Ames, IA; 2. Electrical and Computer Engineering Department, Iowa This is the list of the winners from the 2013 Chicago, IL Joint Conference: State University, Ames, IA; 3. Department of Physics and Astronomy, Iowa Best 12th Joint MMM/Intermag Conference State University, Ames, IA Poster Presentation Winners ES-04. Finite-Size Scaling of Domain Pattern Transfer in Thin- Film AQ-14. Spectroscopic FMR Signature for Anomalous Write Error Ferromagnetic-Ferroelectric Heterostructures. Rate Tail in MTJ MRAM. K. Franke1, T. Lahtinen1 and S. van Dijken1 R. Heindl2, E.R. Evarts1, W.H. Rippard1 and M.R. Pufall1 1. Department of Applied Physics, Aalto University School of Science, 1. National Institute of Standards and Technology, Boulder, CO; Espoo, Finland 2. Department of Physics, San Jose State University, San Jose, CA 8 9

EV-11. Current-perpendicular-to-plane giant magnetoresistance in CHILD CARE SUPPORT pseudo spin valves with Co2Fe(Ge0.5Ga0.5) Heusler alloy ferromagnetic layers and Cu/Ag spacers. The MMM 2013 Conference has awarded a limited number of childcare S. Li1, Y. Takahashi1, H. Goripati2, T. Furubayashi1 and K. Hono1,2 grants, up to $400, available for MMM 2013 meeting attendees who are 1. National Institute for Materials Science, Tsukuba, Japan; 2. Graduate bringing small children to a meeting or who incur extra expenses in leaving School of Pure and Applied Sciences, University of Tsukuba, Tsukuba, their children at home (i.e., extra daycare or babysitting services). The Japan recipients of child care support have been informed about their selection and are required to submit receipts for their reimbursable expenses by Novem- FT-11. Linewidth broadening of vortex based spin transfer ber 22nd. For further information please consult the website at www.mag- nanooscillators. netism.org. Furthermore, if you are interested in this support at future con- 1 1 1 1 2 E. Grimaldi , P. Bortolotti , A. Dussaux , J. Grollier , A. Fukushima , ferences, please consult the same web-site several months before the con- 2 2 2 1 1 H. Kubota , K. Yakushiji , S. Yuasa , V. Cros and A. Fert ference dates. 1. Unité Mixte de Physique CNRS Thales, Palaiseau, France; 2. National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Japan FUTURE CONFERENCES GP-11. Time-resolved Imaging of the Gyrotropic Motion of Magnetic 2014 Intermag Conference Bubbles. May 4-8, 2014, Dresden, Germany F. Büttner1,2, C. Moutafis3, M. Schneider2, C.M. Günther2, J. Mohanty2, J. Geilhufe4, C.v. Korff Schmising2, M. Foerster1, T. Schulz1, J. Franken5, 59th Conference on Magnetism and Magnetic Materials H. Swagten5, M. Kläui1 and S. Eisebitt2,4 November 3-7, 2014, Honolulu, Hawaii 1. Institute of Physics, University of Mainz, Mainz, Germany; 2. Institut 2015 Intermag Conference für Optik und Atomare Physik, Technische Universität Berlin, Berlin, May 4-8, 2015, Beijing, China Germany; 3. Swiss Light Source, Paul Scherrer Institute, Villigen PSI, 13th Joint MMM-Intermag Conference Switzerland; 4. Helmholtz-Zentrum Berlin für Materialien und Energie January 11-15, 2016, San Diego, California GmbH, Berlin, Germany; 5. Technical University Eindhoven, Eindhoven, Netherlands 61st Conference on Magnetism and Magnetic Materials October 31-November 4, 2016, New Orleans, Louisiana GV-07. Chiral nature of forbidden states in artificial spin ice. The 21st International Conference on Magnetism (ICM 2018) H. Riahi1, F. Montaigne1, N. Rougemaille2, B. Canals2, J. Toussaint2, July 16-20, 2018, San Francisco, California M. Hehn1 and D. Lacour1 1. P2M, Institut Jean Lamour (IJL), Vandœuvre-lès-Nancy, France; 2. Institut Néel, CNRS-UJF, Grenoble, France ADDITIONAL INFORMATION HR-01. Transport and Structural Properties of The Abrupt Fe/GaAs(001) Interface. If you would like to receive more information about the 58th MMM Conference, L.R. Fleet1, K. Yoshida2, H. Kobayashi3, Y. Kaneko3, S. Matsuzaka3, to be placed on the Conference Mailing List, or to update your mailing address, Y. Ohno3, S. Honda4, J. Inoue2 and A. Hirohata1,5 please contact Janis Bennett at: [email protected]. The latest information on the 1. The University of York, York, United Kingdom; 2. Nagoya University, 2013 MMM Conference can be found on the Web at the Conference homepage at: Nagoya, Japan; 3. RIEC, Tohoku University, Sendai, Japan; 4. University http://www.magnetism.org/. of Tsukuba, Tsukuba, Japan; 5. PRESTO, Japan Science and Technology Agency, Kawaguchi, Japan CONFERENCE ORGANIZATION HY-05. Three-dimensional display with magnetic hologram composed of a large number of nano-scale magnetic pixels in magnetic thin film Steering Committee 58th MMM Conference with perpendicular magnetization. Chairman ...... Axel Hoffmann Y. Eto1, K. Nakamura1, H. Takagi1, P. Lim1 and M. Inoue1 Chairman Elect ...... Chris Leighton 1. Department of Electrical and Electronic Information Engineering, Past Chairman ...... Paul Crowell Toyohashi University of Technology, Toyohashi, Aichi, Japan Treasurers...... Yumi Ijiri, Maria Varela Program Co-Chairmen...... Andrew Kent, Suzanne te Velthuis CONGRATULATIONS TO ALL!!! Program Committee Members. . . . Adeyeye Adekunle, Charles Ahn, Agustina Asenjo, Dhirendra Bahadur, Katy Barmak, Geoff Beach, Manuel STUDENT TRAVEL AWARDS Bibes, Ekkes Brück, Kristen Buchanan, Robert Camley, Miguel Travel grants are offered to a limited number of students who are presenting Ciria, Nora Dempsey, Cindi Dennis, at the 58th MMM Conference. These students are chosen from among those Jaime Fernandez-Baca, Peter Fischer, who applied online (with advisor’s endorsement), and the grants will be Mike Fitzsimmons, Michael Flatte, used to reimburse partial travel expenses of those students (receipts Kaizhong Gao, Miguel Angel Garcia, required). The program is for students who are presenting at the conference Don Gardner, Gutfleisch, and have not previously received a Conference or Magnetics Society travel Xiufeng Han, Olle Heinonen, Steve grant. Only one application per research group is accepted. Postdoctor- Hill, Yang-Ki Hong, Guonhan Hu, al fellows and non-students are not eligible. If you are interested in apply- Kazushi Ishiyama, Yi Ji, Sam Jiang, ing for a travel grant to attend future magnetics conferences, go to Xiaofeng Jin, Zeke Johnston-Halperin, www.magnetism.org two months prior to the conference dates. Mark Kief, Andre Kirilyuk, Lior Klein, 10 11

Paul Koenraad, Kathryn Krycka, June ACKNOWLEDGEMENTS Lau, J. Ping Liu, Kai Liu, Julia Lyubina, Sara Majetich, Aurelien The conference organizers would like to thank the sponsors of the confer- Manchon, Christopher Marrows, Steve ence, AIP Publishing and the IEEE Magnetics Society, for their financial May, Mike McHenry, Bob McMichael, and logistical support. Furthermore, we would like to express our thanks for Goran Mihajlović, Casey Miller, Paolo these specific financial contributions to support various conference activi- Morais, John Moreland, Markus ties: Münzenberg, Ulrich Nowak, Hendrik Opening Welcome Reception: . . . . IEEE Magnetics Society Ohldag, Yoshichika Otani, Sergio Women in Magnetism Rezende, Stephan Rosenkranz, networking reception ...... IEEE Magnetics Society Thomas Schrefl, Toshiyuki Shima, Internet access ...... IEEE Magnetics Society Jordi Sort, Bethany Stadler, Robert Bierstube Stamps, Yuri Suzuki, Kiyonori Suzuki, (Tuesday and Thursday)...... Materion Tom Thomson, Evgeny Tsymbal, Best Poster Awards...... GMW Paolo Vavassori, Matt Willard Publications Chairman...... Hari Srikanth Publications Editors ...... Cindi Dennis Victorino Franco Olle Heinonen Olga Kazakova P. S. Anil Kumar Ken-ichi Uchida Exhibits Chairman ...... Mingzhong Wu Publicity ...... Brian Maranville Student Awards and Travel ...... Micheal Pechan Beer Chairman ...... John Moreland Editor, J. Appl. Phys...... James Viccaro Conference Management ...... Diane Melton, Jennifer Fiske; Simply Vintage AIPP Coordinator...... Janis Bennett

Advisory Committee 58th MMM Conference Chairman ...... Paul Crowell Chair-Elect ...... Axel Hoffmann Executive Secretary/Treasurer . . . . Yumi Ijiri Recording Secretary...... Diane Melton Term Expires December 2013: . . . Julie Borchers, Bernard Dieny, Claudia Felser, Eric Fullerton, Bo Liu, Mark Stiles, Hari Srikanth, Bruce Terris, Jan Thiele, Shinji Yuasa Term Expires December 2014: . . . Franca Albertini, Dario Arena, Elke Arenholz, Ching-Ray Chang, Jeff Childress, Alina Deac, Yumi Ijiri, Grace Lin, Dan Reich, Matt Willard Term Expires February 2016: . . . Cindi Dennis, Andrew Kent, Kyung- Jin Lee, Laura Lewis, Patrick LeClair, Alan MacDonald, Christopher Marrows, YoshiChika Otani, Amanda Petford-Long, Maria Varela

Sponsoring Society Representatives AIP Publishing ...... Bill Burke IEEE Magnetics Society ...... Massimo Pasquale 12 13

CONFERENCE PROGRAM BV Rare Earth Permanent Magnets II Exhibit Hall BW Nanoparticles in Arrays I Ballroom A Monday 2:00 pm to 5:30 pm BX Micromagnetics - numerical methods Ballroom A XA Tutorial: Berry Phases in Magnetism Ballroom BC Tuesday Eve 6:00 pm to 7:00 pm Tuesday 8:30 am to 11:30 am YA Evening Session: Magnetism in Ballroom BC AA Symposium on Exploring new frontiers Ballroom BC Atomic Systems in magnetism using x-rays AB Spin Transport and Dynamics Ballroom F Wednesday 8:30 am to 11:30 am AC Magnonics: Controlling Spin Waves Ballroom E CA Symposium on Spin injection and transport Ballroom BC in organic materials AD Exchange Bias I Ballroom D CB Dynamics: Spin Torque Oscillators and Ballroom F AE Multiferroics I: Materials and Phenomena Governor’s Sq 14 Tunnel Junctions AF Intermetallics and Other Hard Magnetic Governor’s Sq 15 CC Multilayers I: Perpendicular Anisotropy and Ballroom E Materials I Interface Effects AG Ultra-Thin Film Magnetism I Governor’s Sq 16 CD MRAM and Magnetic Logic Devices I Ballroom D AH Micromagnetic modeling I Governor’s Sq 12 CE Electric and Strain Effects on Magnetism Governor’s Sq 14 and Transport 9:30 am to 12:30 pm CF Magnetocalorics and Magnetoelastics I Governor’s Sq 15 AP Multilayers and Thin Films Exhibit Hall CG Soft Magnets: Amorphous and Governor’s Sq 16 AQ Frustration and Low-Dimensional Systems Exhibit Hall Nanocomposite II AR Soft Magnets: Amorphous and Exhibit Hall CH Magnetic Sensors Governor’s Sq 12 Nanocomposite I AS Magnetic Sensors (Not for recording) Exhibit Hall 9:30 am to 12:30 pm AT Magneto-Optic and New Magnetic Materials I Exhibit Hall CP Spin Transfer and Spin Hall Effects Exhibit Hall AU Interacting Domain Walls Exhibit Hall CQ Critical Phenomena and Electronic Structure Exhibit Hall AV Boride Permanent Magnets: Fundamentals Exhibit Hall CR Wireless and Soft Magnet Applications Exhibit Hall and Advanced Characterization I CS Superconductivity and Complex Oxides Exhibit Hall AW New Applications and Measurements Ballroom A CT Bit-patterned and energy-assisted Exhibit Hall AX Semiconductor Magnetism I Ballroom A recording media CU Magnetization Dynamics: FMR and Damping Exhibit Hall 1:30 pm to 4:30 pm CV Energy Harvesting, Generators, and Levitation Exhibit Hall BA Symposium on Materials advances of Ballroom BC spin-torque switched memory devices for CW Metallic, Non-Oxide, and Core-Shell Ballroom A silicon intergration Nanoparticles BB Controlling Domain Walls Ballroom F CX Hexaferrites and Garnets Ballroom A

BC Damping and Spin Pumping Ballroom E 1:30 pm to 4:30 pm BD Fundamental Properties and Cooperative Ballroom D DA Symposium on Nonlinear magnetization Ballroom BC Phenomena I: Correlated systems and dynamics induced by spin-transfer torque Superconductivity DB Domain Wall Dynamics Ballroom F BE Complex Oxides: films and heterostructures Governor’s Sq 14 DC Tunnel Magnetoresistance II Ballroom E BF Rare Earth Permanent Magnets I Governor’s Sq 15 DD Frustrated Magnetism and Critical Ballroom D BG Skyrmions and Vortices Governor’s Sq 16 Phenomena BH Bio Applications: Nanoparticles and Governor’s Sq 12 DE Magnetic Nanoparticles I Governor’s Sq 14 Microfluidics DF Rare Earth-Free Permanent Magnets I Governor’s Sq 15 2:30 pm to 5:30 pm DG Soft Magnets: Thin Film Materials II Governor’s Sq 16 BP Spin Pumping and Spin Injection Exhibit Hall DH Spin Hall Effects Governor’s Sq 12 BQ Hysteresis modeling Exhibit Hall 2:30 pm to 5:30 pm BR Soft Magnetic Thin Films I Exhibit Hall DP Spin Transport Exhibit Hall BS Tunnel Magnetoresistance I Exhibit Hall DQ Fundamental Properties and Cooperative Exhibit Hall BT Heat-assisted Magnetic Recording Exhibit Hall Phenomena II: Correlated Systems BU Magnonics Exhibit Hall DR Microstructures for Microwave Applications Exhibit Hall 14 15

DS Magnetoelectric Structures and Phenomena Exhibit Hall FU Tailoring Domain Walls Exhibit Hall DT Continuous Granular Media for Magnetic Exhibit Hall FV Intermetallics and Other Hard Magnetic Exhibit Hall Recording Materials III DU Imaging and Novel Approaches Exhibit Hall FW Magnetic Fluids Ballroom A DV Intermetallics and Other Hard Magnetic Exhibit Hall FX Semiconductor Magnetism II Ballroom A Materials II DW Oxide Nanoparticles Ballroom A Thursday Eve 6:00 pm to 7:00 pm DX Micromagnetic modeling II Ballroom A ZA Evening Session: Skrymions and the Ballroom BC Spin Hall Effect, what are they good for? Thursday 8:30 am to 11:30 am Friday 8:30 am to 11:30 am EA Symposium on Trends in Magnetic Imaging Ballroom BC GA Symposium on Emergent Phenomena Ballroom BC EB Tunneling and Spin Transport I Ballroom F in Magnetism EC Spin-caloritronics and Spin Hall Effects Ballroom E GB Voltage Control of Anisotropy, Ballroom F ED Electronic Structure and Critical Phenomena Ballroom D Magnetoresistance II EE Magnetic Nanoparticles II Governor’s Sq 14 GC Spin Pumping, Spin Transfer and Ballroom E EF Fe- and RE-based Magnetocalorics Governor’s Sq 15 Spin Injection EG Transformers and Inductors Governor’s Sq 16 GD Magneto-Optic and New Magnetic Ballroom D Materials II EH Spin Transfer Dynamics Governor’s Sq 12 GE Magnetic Patterned Films II Governor’s Sq 14 9:30 am to 12:30 pm GF Permanent Magnet Processing II Governor’s Sq 15 EP Exchange Bias II Exhibit Hall GG Soft Magnet Applications Governor’s Sq 16 EQ Complex Oxides Exhibit Hall GH Interface Effects for Magnetic Governor’s Sq 12 ER Soft Magnetic Steels and Alloys Exhibit Hall Semiconductors, Heuslers and Other Half-Metallics ES Voltage Control of Anisotropy, Exhibit Hall Magnetoresistance I 9:30 am to 12:30 pm ET Ultra-Thin Film Magnetism II Exhibit Hall GP Vortices and rings Exhibit Hall EU Magnetization Dynamics: Ultrafast Exhibit Hall GQ Magnetocalorics and Magnetoelastics II Exhibit Hall Dynamics and Spin Waves GR Instrumentation and Bio Imaging Exhibit Hall EV Permanent Magnet Processing I Exhibit Hall GS Multiferroics III: Effects of Doping and Exhibit Hall EW Nanoparticles: Measurements and Ballroom A Nanocomposition Bio Applications GT MRAM and Magnetic Logic Devices II Exhibit Hall EX Spinels for High Frequency Applications Ballroom A GU Tunneling and Spin Transport II Exhibit Hall 1:30 pm to 4:30 pm GV Rare Earth-Free Permanent Magnets II Exhibit Hall FA Symposium on Spin Hall and Rashba Ballroom BC GW Magnetic recording - modeling Ballroom A effects in magnetic bilayers FB Ultrafast Dynamics Ballroom F 1:30 pm to 4:30 pm FC Advanced Microscopy and Characterization Ballroom E HA Symposium on Electric field control of Ballroom BC magnetic properties FD Low-Dimensional and Molecular Magnetism Ballroom D HB Spin Injection into Semiconductors Ballroom F FE Energy-assisted recording media Governor’s Sq 14 HC Multilayers II: Exchange Coupling and Ballroom E FF Boride Permanent Magnets: Fundamentals Governor’s Sq 15 Spin-Transport and Advanced Characterization II HD Microwave and Millemeter Wave Materials Ballroom D FG Metamaterials and Microwave Devices Governor’s Sq 16 HE Nanoparticles in Arrays II Governor’s Sq 14 FH Bio Applications: Hyperthermia and Imaging Governor’s Sq 12 HF Granular Media for Recording Governor’s Sq 15 2:30 pm to 5:30 pm HG Micro-Electro-Mechanical Systems (MEMS) Governor’s Sq 16 FP Magnetic Patterned Films I Exhibit Hall HH Complex Oxides (bulk) Governor’s Sq 12 FQ Novel Magnetocalorics Exhibit Hall FR Soft Magnetic Nanoparticles Exhibit Hall FS Multiferroics II: Materials and Phenomena Exhibit Hall FT Heads, head-media interface, and tribology Exhibit Hall 16 PROGRAM 17

MONDAY PLAZA BALLROOM BC AFTERNOON 2:00

Session XA TUTORIAL: BERRY PHASES IN MAGNETISM Axel Hoffmann, Chair

2:00 XA-01. Berry Phases in momentum-space. (Invited) J. Sinova1,21. Texas A&M University, College Station, TX; 2. Institute of Physics ASCR, Prague, Czech Republic

2:45 XA-02. Real-Space Berry Phases – Skyrmion Soccer. (Invited) K. Everschor-Sitte1,21. Department of Physics, TU Munich, Garching, Germany; 2. Institute for Theoretical Physics, University of Cologne, Köln, Germany

3:30 XA-03. Experimental studies of Berry phase induced Hall effects. (Invited) Y. Onose11. Basic Science, University of Tokyo, Tokyo, Tokyo, Japan

TUESDAY PLAZA BALLROOM BC MORNING 8:30

Session AA SYMPOSIUM ON EXPLORING NEW FRONTIERS IN MAGNETISM USING X-RAYS Hendrik Ohldag, Chair

8:30 AA-01. Exploring the Ultrafast Magnetic Nanoworld with X-Ray Laser Pulses. (Invited) J. Stohr11. SLAC, Menlo Park, CA

9:06 AA-02. Femtosecond XMCD measurements of spin and orbital momentum in magnetic alloys. (Invited) C. Stamm11. Department of Materials, ETH Zurich, Zurich, Switzerland

9:42 AA-03. Hard x-ray absorption spectroscopy: correlating local structure and valence with magnetism. (Invited) A. Ney1, V. Ney1, F. Wilhelm2, K. Ollefs2 and A. Rogalev21. Solid State Physics, Johannes Kepler University, Linz, Austria; 2. European Synchrotron Radiation Facility, Grenoble, France 18 PROGRAM PROGRAM 19

10:18 9:30 AA-04. Imaging Magnetic Vortices using XMCD and XMLD. (Invited) AB-04. Pillar Size Dependence of Peltier Cooling Effect in Heusler 1 Z.Q. Qiu 1. University of California at Berkeley, Berkeley, CA Compounds Co2YSi (Y = Mn, Fe) / NM (NM = Au, Cu) Current Perpendicular to Plane Nano Junctions. S. Bosu1, Y. Sakuraba1, T. Kubota1, T. Sugiyama1, K. Saito1 and 10:54 K. Takanashi11. Institute for Materials Research, Tohoku AA-05. The High-Resolution Synchrotron X-ray Scanning Tunneling University, Sendai, Japan Microscope (SXSTM) for Chemical Electronic and Magnetic 1 1 1 Imaging. (Invited) M. Cummings , N. Shirato , B. Stripe , 9:42 C. Preissner1, D. Rosenmann2, S. Hla2 and V. Rose1,21. Advanced Photon Source, Argonne National Laboratory, Argonne, IL; 2. AB-05. Determination of Spin Polarization of Fe65Si35 Using Center for Nanoscale Materials, Argonne National Laboratory, Andreev Reflection Spectroscopy. J. Martinez1, J.A. Gifford1, Argonne, IL C.N. Snider1 and T.Y. Chen11. Physics, Arizona State University, Tempe, AZ

9:54 TUESDAY PLAZA BALLROOM F AB-06. High Field Magnetotransport and Point Contact Andreev MORNING Reflection Spin Polarisation Measurements on CuCr2Se4 and CuCr Se Br - Degenerate Magnetic Semiconductor Single 8:30 2 3 Crystals. K. Borisov1, J. Alaria2, J. Coey1 and P. Stamenov11. School of Physics and CRANN, Trinity College Dublin, Dublin, Session AB Ireland; 2. Department of Physics, University of Liverpool, SPIN TRANSPORT AND DYNAMICS Liverpool, United Kingdom Paul Crowell, Chair 10:06 8:30 AB-07. Andreev effect in GaMnAs/Nb microstructures: the crucial 1 1 AB-01. Giant topological Hall effect in strained Fe Co Si epilayers. role of the interface treatment. K. Eid , H. Abu Jeib , 0.7 0.3 1 1 1 1 2 (Invited) N. Porter1, P. Sinha1, M. Ward2, R. Brydson2, D. Dahliah , J. Guenther , R. Tolley , T. Reid , X. Liu and 2 A. Dobrynin3, T. Charlton4, C. Kinane4, S. Langridge4 and J. Furdyna 1. Physics, Miami University, Oxford, OH; 2. Physics, C. Marrows11. School of Physics and Astronomy, University of University of Notre Dame, Notre Dame, IN Leeds, Leeds, United Kingdom; 2. SPEME, University of Leeds, Leeds, United Kingdom; 3. Diamond Light Source, Didcot, United 10:18 Kingdom; 4. ISIS, STFC Rutherford Appleton Laboratory, Didcot, United Kingdom AB-08. Annealing temperature dependence of g-factor and Damping constant of Half-metallic co-sputtered Co2FeAl thin films. A. Yadav1 and S. Chaudhary11. Physics, IIT Delhi, Hauz Khas, 9:06 Delhi, India AB-02. The Origin of the Crossover from Weak Antilocalization to Weak Localization in Magnetic Topological Insulators. 10:30 B.A. Assaf1, P. Wei2, F. Katmis2,3, J.S. Moodera2,3 and D. Heiman11. Physics, Northeastern University, Boston, MA; 2. AB-09. Enhanced perpendicular magnetic anisotropy and tunnel Francis Bitter Magnet Lab, MIT, Cambridge, MA; 3. Physics, magnetoresistance in Co2FeAl full-Heusler alloy magnetic 1 1 MIT, Cambridge, MA tunnel junctions with a Ru buffer. Z. Wen , H. Sukegawa , T. Furubayashi1, K. Inomata1 and S. Mitani11. National Institute for Materials Science, Tsukuba, Japan 9:18

AB-03. Voltage control of thermal spin current in a ferromagnetic 10:42 tunnel contact to silicon. K. Jeon1, A. Spiesser1, H. Saito1, 1 2 1 S. Yuasa , B. Min and R. Jansen 1. Spintronics Research Center, AB-10. X-ray magnetic circular dichroism for Co3FeN films grown by 1 1 1 National Institute of Advanced Industrial Science and Technology molecular beam epitaxy. K. Ito , T. Sanai , Y. Yasutomi , 2 1 3 3 2 (AIST), Tsukuba, Ibaraki, Japan; 2. Center for Spintronics S. Zhu , K. Toko , Y. Takeda , Y. Saitoh , A. Kimura and 1 Research, Korea Institute of Science and Technology (KIST), T. Suemasu 1. Institute of Applied Physics, University of Tsukuba, Seoul, Republic of Korea Tsukuba, Ibaraki, Japan; 2. Graduate School of Science, Hiroshima University, Higashi-hiroshima, Hiroshima, Japan; 3. Condensed Matter Science Division, Japan Atomic Energy Agency, Sayo-cho, Hyogo, Japan 20 PROGRAM PROGRAM 21

10:54 9:18 AB-11. Structural ordering dependence of magnetic properties in the AC-03. Magnonic modes in three-dimensional permalloy/cobalt Heusler compound Mn2FeGa. A.K. Nayak1, T. Gasi2, binary systems.P. Malagò1, R. Zivieri1 and L. Giovannini11. A. Kalache1, M. Nicklas1 and C. Felser11. Max Planck Institute Department of Physics and Earth Sciences, University of Ferrara, for Chemical Physics of Solids, Dresden, Germany; 2. Institut for Ferrara, Italy Inorganic and Analytical Chemistry, Johannes Gutenberg University, Mainz, Germany 9:30

11:06 AC-04. Comparison of dynamic interaction in close-packed rectangular and circular thin film magnetic rings. AB-12. Survey of Full Heuslers with a Focus on Highly Spin- G. Shimon1,2, A.O. Adeyeye1,2 and C.A. Ross2,31. Electrical and Polarized Low Moment Materials. J.C. Romero1,2 and Computer Engineering, National University of Singapore, W.H. Butler1,21. MINT, University of Alabama, Tuscaloosa, AL; 2. Singapore, Singapore; 2. Singapore-MIT Alliance, Singapore, Physics and Astronomy, University of Alabama, Tuscaloosa, AL Singapore; 3. Materials Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA 11:18 9:42 AB-13. Extraction of g-factor using interaction between Rashba and Zeeman splittings. W. Choi1,2, J. Chang1, J. Lee1 and H. Koo1,21. AC-05. Asymmetric frequency dispersions of equivalent spin wave Spin Convergence Research Center, Korea Institute of Science modes measured along symmetry directions of a hexagonal and Technology, Seoul, Republic of Korea; 2. KU-KIST Graduate magnonic crystal. F. Montoncello1, S. Tacchi2, L. Giovannini1, School of Converging Science and Technology, Korea University, M. Madami3, G. Gubbiotti2, G. Carlotti3, E. Sirotkin4, E. Ahmad4, Seoul, Republic of Korea F.Y. Ogrin4 and V.V. Kruglyak41. Dipartimento di Fisica a Scienze della Terra, University of Ferrara and CNISM, Ferrara, Italy; 2. Istituto Officina dei Materiali del Consiglio Nazionale delle Ricerche-Unità di Perugia, Perugia, Italy; 3. Dipartimento di Fisica, University of Perugia and CNISM, Perugia, Italy; 4. TUESDAY PLAZA BALLROOM E School of Physics, University of Exeter, Exeter, United Kingdom MORNING 8:30 9:54 AC-06. Magnonic crystals made from Permalloy film on top of 2-D Session AC dot array. X. Liu1, J. Ding1, G.N. Kakazei1 and A.O. Adeyeye11. MAGNONICS: CONTROLLING SPIN WAVES Electrical and Computer Engineering, National University of Alexander Serga, Chair Singapore, Singapore, Singapore

8:30 10:06 AC-01. Berry curvature, Hall effect, and Topological Phases of AC-07. Control of propagating spin wave attenuation by the spin-Hall 1 1 Magnetostatic Spin Waves. (Invited) R. Shindou1,2, J. Ohe3, effect. S. Woo and G.S. Beach 1. Materials Sci. & Eng., MIT, R. Matsumoto1, S. Murakami1 and E. Saitoh41. Department of Cambridge, MA Physics, Tokyo Institute of Technology, Tokyo, Japan; 2. International Center for Quantum Materials, Peking University, 10:18 Beijing, China; 3. Department of Physics, Toho University, Funabashi, Japan; 4. Institute for Materials Research, Tohoku AC-08. Influence of laser power on Bose-Einstein condensate and 1 University, Sendai, Japan magneto-elastic magnon mode in a magnon gas. P. Clausen , D.A. Bozhko1,2, V.I. Vasyuchka1, A.V. Chumak1, A.A. Serga1, G.A. Melkov2 and B. Hillebrands11. Fachbereich Physik and 9:06 Landesforschungszentrum OPTIMAS, TU Kaiserslautern, AC-02. Propagation of spin waves in dense nanostripes array with Kaiserslautern, Germany; 2. Faculty of Radiophysics, Taras step-modulated thickness. G. Gubbiotti1, S. Tacchi1, Shevchenko National University of Kyiv, Kyiv, Ukraine M. Madami2, G. Carlotti2, J. Ding3, A.O. Adeyeye3, M. Kostylev4, F. Zighem5, A. Khor4 and S. Samarin41. IOM-CNR, Perugia, Italy; 2. Dipartimento di Fisica, Università di Perugia, Perugia, Italy; 3. Department of Electrical and Computer Engineering, National University of Singapore, Singapore, Singapore; 4. School of Physics M013, University of Western Australia, Perth, WA, Australia; 5. Laboratoire des Propriétés Mécaniques et Thermodynamiques des Matériaux, CNRS, Institut Galilée, Université Paris-Nord,, Villetaneuse, France 22 PROGRAM PROGRAM 23

10:30 TUESDAY PLAZA BALLROOM D AC-09. Spin wave device using voltage-controlled magnetic MORNING anisotropy at MgO/CoFeB interface. M. Yamada1, K. Miura1, 8:30 O. Rousseou2, Y. Fukuma2,3, S. Ogawa1 and Y. Otani2,41. Central Research Laboratory, Hitachi, ltd., Tokyo, Japan; 2. Center for Session AD Emergent Matter Science, Riken, Saitama, Japan; 3. Frontier EXCHANGE BIAS I Research Academy for Young Researchers, Kyushu Institute of Technology, Fukuoka, Japan; 4. Institutes for Solid State Physics, Edwin Fohtung, Chair University of Tokyo, Chiba, Japan 8:30 10:42 AD-01. On the Intrinsic or Extrinsic Exchange Bias Feature of AC-10. Impact of the intrinsic and extrinsic symmetry breaking on Antiferromagnetic NiO Nanoparticles Produced by the Polyol 1 1 1 2 the spin wave spectrum in periodic waveguide. J.W. Klos1, Process. T. Gaudisson , L. Mouton , S. Nowak , F. Mazaleyrat 1 D. Kumar2, M. Krawczyk1 and A. Barman21. Faculty of Physics, and S. Ammar 1. ITODYS, Université Paris Diderot, PRES Adam Mickiewicz University in Poznan, Poznan, Poland; 2. Sorbonne Paris Cité, CNRS-UMR 7086 Diderot, 75205 Paris Department of Condensed Matter Physics and Material Sciences, Cedex, France; 2. SATIE, ENS Cachan, CNRS, F-94230, Cachan, S. N. Bose National Centre for Basic Sciences, Kolkata, India France

10:54 8:42 AC-11. Four-magnon instabilities in a micro-structured AD-02. Exchange bias and anomalous virgin curve behavior in 1,2 3 4 Co Mn Fe Si spin-wave conduit. A.A. Serga1, P. Pirro1, nanocrystalline spinels. U.S. Alaan , S. Gollapudi , F.J. Wong , 2 0.6 0.4 4,1 4,1 5 5 T. Brächer1,2, T. Sebastian1, T. Kubota3, Y. Ohdaira4, J.M. Iwata-Harms , A.J. Grutter , C. Jenkins , E. Arenholz , 3 1,6 H. Naganuma4, M. Oogane4, Y. Ando4 and B. Hillebrands11. G. Srinivasan and Y. Suzuki 1. Geballe Laboratory for Fachbereich Physik and Landesforschungszentrum OPTIMAS, Advanced Materials, Stanford University, Stanford, CA; 2. Technische Universität Kaiserslautern, Kaiserslautern, Germany; Materials Science and Engineering, Stanford University, Stanford, 2. Graduate School Materials Science in Mainz, Mainz, Germany; CA; 3. Physics, Oakland University, Rochester, MI; 4. Materials 3. WPI Advanced Institute for Materials Research, Tohoku Science and Engineering, University of California, Berkeley, University, Sendai, Japan; 4. Department of Applied Physics, Berkeley, CA; 5. Advanced Light Source, Lawrence Berkeley Graduate School of Engineering, Tohoku University, Sendai, National Laboratory, Berkeley, CA; 6. Applied Physics, Stanford Japan University, Stanford, CA

11:06 8:54 AC-12. One-dimensional magnonic crystals of dipolar-coupled vortex AD-03. Exchange bias via superexchange coupling in a Fe-film/CoO- 1 1 lattices. D. Han1, A. Vogel2, H. Jung1, K. Lee1, M. Weigand3, nanoparticle hybrid system. W. Zhang , T. Wen and 1 H. Stoll3, G. Schütz3, P. Fischer4, G. Meier2 and S. Kim11. K.M. Krishnan 1. Materials Science and Engineering, University Department of Materials Science and Engineering College of of Washington, Seattle, WA Engineering, Seoul National University, Seoul, Republic of Korea; 2. Institut für Angewandte Physik und Zentrum für 9:06 Mikrostrukturforschung, Universität Hamburg, Hamburg, Germany; 3. Max-Planck-Institut für Intelligente Systeme,, AD-04. Magnetic control of Sm1-xGdxAl2, a zero-magnetization 1 1 2 Stuttgart, Germany; 4. Center for X-ray Optics, Lawrence ferromagnet. K. Dumesnil , M. Bersweiler , F. Wilhelm and 2 Berkeley National Laboratory, Berkeley, CA A. Rogalev 1. P2M, Institut Jean Lamomur, Vandoeuvre les Nancy, France; 2. ESRF, Grenoble, France

11:18 9:18 AC-13. Normal mode study of a single skyrmion in geometrically 1 1 confined thin film nanostructures. M. Beg , D. Chernyshenko , AD-05. Multiple Phased GdxFe1-x/NiCoO Thin Films with Field- 1 1 1 M. Bisotti1, W. Wang1, M. Albert1, R. Stamps2 and H. Fangohr11. Tunable Exchange Bias. D.A. Gilbert , J. Olamit , R.K. Dumas , 2 1 University of Southampton, Southampton, United Kingdom; 2. E. Arenholz and K. Liu 1. Physics, University of California, University of Glasgow, Glasgow, United Kingdom Davis, CA; 2. Advanced Light Source, Lawrence Berkeley National Laboratory, Berkeley, CA

9:30 AD-06. Origin of perpendicular magnetic anisotropy of Co-Pt film on 1 1 1 Cr2O3 antiferromagnetic oxide. T. Nozaki , M. Oida , T. Ashida and M. Sahashi11. Electronic Engineering, Tohoku University, Sendai, Miyagi, Japan 24 PROGRAM PROGRAM 25

9:42 11:18

AD-07. How Antiferromagnetism Drives the Magnetization of a AD-13. Optimisation of exchange bias in Co2FeAl0.5Si0.5 Heusler alloy Ferromagnetic Thin Film to Align Out of Plane. (Invited) layers. A. Hirohata1,2, K. Izumida3, R. Ishizawa3, J. Sagar4 and M. Lin1,21. Physics, National Taiwan University, Taipei, Taiwan; T. Nakayama31. Department of Electronics, University of York, 2. Institute of Atomic and Molecular Sciences, Academia Sinica, York, United Kingdom; 2. PRESTO, Japan Science and Taipei, Taiwan Technology Agency, Kawaguchi, Japan; 3. Department of Electronic Engineering, Nagaoka University of Technology, Nagaoka, Japan; 4. Department of Physics, University of York, 10:18 York, United Kingdom AD-08. Exchange bias enhancement in [Pt(Pd)/Co]/IrMn/Co trilayers with ultrathin IrMn through Cu interlayer. G. Vinai1,2, J. Moritz2, S. Bandiera1, I. Prejbeanu2 and B. Dieny21. Crocus Technology, Grenoble, France; 2. Spintec, Grenoble, France TUESDAY GOVERNOR’S SQ 14 10:30 MORNING 8:30 AD-09. Role of Cu in Intrinsic Exchange Bias in FeMn.P.N. Lapa1, D. Kaya1, E. Skoropata2, J. van Lierop2, H. Kirby3, P. Jayathilaka3, C.W. Miller3 and I.V. Roshchin1,41. Department of Physics and Session AE Astronomy, Texas A&M Univ, College Station, TX; 2. Department MULTIFERROICS I: MATERIALS AND of Physics and Astronomy, University of Manitoba, Winnipeg, MB, PHENOMENA Canada; 3. Department of Physics, University of South Florida, Tampa, FL; 4. Materials Science and Engineering Program, William Ratcliff, Chair Texas A&M University, College Station, TX 8:30 10:42 AE-01. Collective magnetism at multiferroic vortex domain walls. 1 1 2 2 1 AD-10. Exchange Bias in Stressed Interfaces. J. de la Venta1,2, W. Wu , Y. Geng , N. Lee , Y. Choi and S. Cheong 1. Physics and 1 1 1 Astronomy, Rutgers University, Piscataway, NJ; 2. Department of A. Basaran , T. Saerbeck and I. Schuller 1. Department of Physics and IPAP, Yonsei University, Seoul, Republic of Korea Physics and Center for Advanced Nanoscience (CAN), UC San Diego, La Jolla, CA; 2. Department of Physics, Colorado State University, Fort Collins, CO 8:42 AE-02. Controlling the magnonic and spintronic response of BiFeO3 10:54 films by epitaxial strain. C. Toulouse1, D. Sando2, M. Cazayous1, J. Juraszek3, A.K. Zvezdin4,5, L. Bellaiche6, B. Dkhil7, AD-11. Mode Softening and Bias Distribution of an Exchange Biased 2 2 1 1 1 A. Barthélémy and M. Bibès 1. Laboratoire Matériaux et NiFe/FeMn Multilayer. R. Stamps , G. Paterson , F. Gonçalves , S. McFadzean1, S. McVitie1, S. O’Reilly2, R.M. Bowman2 and Phénomènes Quantiques (UMR 7162), Université Paris Diderot - 3 Paris 7, Paris, France; 2. Unité Mixte de Physique CNRS/Thales, D. Schmool 1. SUPA-School of Physics and Astronomy, Thales, Palaiseau, France; 3. Groupe de Physique des Matériaux University of glasgow, Glasgow, United Kingdom; 2. ANSIN, (UMR 6634), Université de Rouen, Rouen, France; 4. Prokhorov Department of Physics and Astronomy, Queen’s University of General Physics Institute, Russian Academy of Sciences, Moscow, Belfast, Belfast, United Kingdom; 3. Department of Physics and Russian Federation; 5. Moscow Institute of Physics and Astronomy, University of Porto, Porto, Portugal Technology, State University, Moscow, Russian Federation; 6. Physics Department and Institute for Nanoscience and 11:06 Engineering, University of Arkhansas, Fayetteville, AR; 7. Laboratoire SPMS (UMR 8580), Ecole Centrale Paris, Châtenay- AD-12. The antiferromagnetic structures of IrMn and their influence 3 Malabry, France on exchange-bias. A. Kohn1,2, A. Kovács3, R. Fan4, G.J. McIntyre5, R.C. Ward6 and J.P. Goff71. Department of Materials Engineering, Ben Gurion University of the Negev, Beer- 8:54 Sheva, Israel; 2. Ilse Katz Institute for Nanoscale Science and Technology, Ben Gurion University of the Negev, Beer-Sheva, AE-03. Influence of Mn doping on the bimodal distribution of blocking temperature for multiferroic-epitaxial-BiFe1- Israel; 3. Ernst Ruska-Centre for Microscopy and Spectroscopy 1 2 2 with Electrons, Peter Grünberg Institute, Forschungszentrum xMnxO3/CoFeB bilayers.C.K. Safeer , J. Allibe , C. Carretero , C. Deranlot2, E. Jacquet2, J. Jacquot3, M. Bibes2, A. Barthélémy2, Jülich, Jülich, Germany; 4. Diamond Light Source, Didcot, 1 1 1 United Kingdom; 5. Australian Nuclear Science and Technology B. Dieny , H. Béa and V. Baltz 1. SPINTEC, Grenoble, France; Organisation, Lucas Heights, NSW, Australia; 6. Clarendon 2. UMR CNRS-Thales, Palaiseau, France; 3. CEA/INAC/SCIB, Laboratory, Department of Physics, University of Oxford, Oxford, Grenoble, France United Kingdom; 7. Department of Physics, Royal Holloway, University of London, Egham, United Kingdom 26 PROGRAM PROGRAM 27

9:06 10:54 AE-04. Uncovering direct magnetoelectric behavior in EuTiO3. AE-11. Magnetic structure of Sm-doped BiFeO3 thin films. (Invited) P. Ryan11. X-ray Science Division, Argonne National S. Maruyama1, V. Anbusathaiah1, A. Poole2, W. Ratcliff II3 and Laboratory, Argonne, IL I. Takeuchi11. Department of Materials Science and Engineering, University of Maryland, College Park, MD; 2. Paul Scherrer Institut, Villigen, Switzerland; 3. Center for Neutron Research, 9:42 National Institute of Standards and Technology, Gaithersburg, AE-05. Anomalies at Neel Temperature in YMnO3 epitaxial films. MD N. Fujimura1, H. Uga1, A. Ashida1 and T. Yoshimura11. Graduate School of Engineering, Osaka Prefecture University, Sakai, 11:06 Osaka, Japan AE-12. Investigation of 3d-3d and 3d-5d Oxides with Double Perovskite structure as Potential Room-Temperature 9:54 Multiferroics. V. Shabadi1, M. VafaeeKhanjani1, AE-06. Neutron Investigations of Multiferroic LuFeO3. W.D. Ratcliff1, M. BaghaieYazdi1, A. Radetinac1, P. Komissinskiy1 and L. Alff11. J.W. Lynn1, Y. Oh2 and S.W. Cheong21. NCNR, NIST, Institute of Materials Science, Technische Universität Darmstadt, Gaithersburg, MD; 2. Physics, Rutgers, New Brunswick, NJ Darmstadt, Hessen, Germany

10:06 11:18 AE-07. Direct visualization of magnetoelectric domains in hexagonal AE-13. The multiferroic properties of polycrystalline Bi1-xYxFeO3 ErMnO3 [1]. Y. Geng1*, H. Das2, A.L. Wysocki2, N. Lee1, films.Y. Sheng1, W. Rui2, X. Qiu3, J. Du2, S. Zhou4 and Q. Xu11. Y. Choi1, S. Cheong1, M. Mostovoy3, C.J. Fennie2 and W. Wu11. Department of Physics and Key Laboratory of MEMS of the Department of Physics and Astronomy, Rutgers University, Ministry of Education, Southeast University, Nanjing, China; 2. Piscataway, NJ; 2. School of Applied and Engineering Physics, National Laboratory of Solid State Microstructures and Cornell University, Ithaca, NY; 3. Zernike Institute for Advanced Department of Physics, Nanjing University, Nanjing, Jiangsu, Materials, University of Groningen, Nijenborgh, Groningen, China; 3. Department of Materials Science and Engineering, Netherlands Nanjing University, Nanjing, Jiangsu, China; 4. Institute of Ion Beam Physics and Materials Research, Helmholtz-Zentrum Dresden-Rossendorf (HZDR) e.V., Dresden, Germany 10:18 AE-08. Templated perovskite/spinel magnetoelectric nanocomposites. N. Aimon1*, D. Kim1, H. Choi1, X. Sun1 and C.A. Ross11. Materials Science and Engineering, MIT, Cambridge, MA TUESDAY GOVERNOR’S SQ 15 10:30 MORNING 8:30 AE-09. Driving the spin excitations in BiFeO3 from spiral to canted 1 1 1 state using pressure. J. Buhot , M. Méasson , M. Cazayous , Session AF Y. Gallais1, A. Sacuto1, A. Forget2 and D. Colson21. Laboratoire Matériaux et Phénomènes Quantiques, UMR 7162 CNRS, INTERMETALLICS AND OTHER HARD Université Paris Diderot - Paris 7, Paris, France; 2. Service de MAGNETIC MATERIALS I Physique de l’Etat Condensé, DSM/DRECAM/SPEC, CEA Saclay, Jerrold Floro, Co-Chair Gif-sur-Yvette, France Felix Jimenez-Villacorta, Co-Chair

10:42 8:30

AE-10. Magnetic Orders and Anisotropy in Mn1-xCoxWO4 1 1 2 Multiferroics.I. Urcelay-Olabarria , E. Ressouche , A. Mukhin , AF-01. Tuning magnetic anisotropy in (001) oriented L10 (Fe1- 1 2 2 3 4 5 V. Ivanov , J. Padilla , V. Pomjakushin , V. Skumryev and xCux)55Pt45 films. (Invited) D.A. Gilbert , L. Wang , 3 3 2 1 J. Garcia-Muñoz31. Institut Laue-Langevin, Grenoble, France; 2. T.J. Klemmer , J. Thiele , C. Lai and K. Liu 1. Physics Prokhorov General Physics Institute of the Russian Academy of Department, University of California, Davis, CA; 2. Department Science, Moscow, Russian Federation; 3. Institut de Ciència de of Materials Science and Engineering, National Tsing Hua Materials de Barcelona -CSIC, Bellaterra, Catalunya, Spain; 4. University, Hsinchu, Taiwan; 3. Seagate Technology, Fremont, CA Paul Scherrer Institute, Villigen, Switzerland; 5. Institut Català de Recerca i Estudis Avançats (ICREA) and Univ. Autònoma de 9:06 Barcelona, Bellaterra, Catalunya, Spain AF-02. Magnetic response in Co-Pt alloys in and near the L10 – L12 coexistence region.P. Ghatwai1, M. Hrdy1, E. Vetter1, J. Floro1 and W.A. Soffa11. Materials Sceince and Engineering, University of Virginia, Charlottesville, VA 28 PROGRAM PROGRAM 29

9:18 10:42 AF-03. Electron theory of perpendicular magnetic anisotropy of Co- AF-10. Exchange coupling in MnBi/Fe-Co Thin-Film bilayers. ferrite thin films. J. Inoue1, H. Yanagihara1 and E. Kita11. L. Fang1, T. Gao1, S. Fackler1, S. Maruyama1, I. Takeuchi1, University of Tsukuba, Tsukuba, Japan D. Johnson2,3, M.J. Kramer2,3, E. Arenholz4, R. Skomski5, S. Lofland6, J. Borchers7, B. Kirby7, W. Ratcliff7 and J. Cui81. Department of Material Sciences and Engineering, University of 9:30 Maryland, College Park, MD; 2. Ames laboratory, Ames, IA; 3. AF-04. Microscopic origin of magnetic anisotropy in $L1_0$-type Department of Materials Science and Engineering, Iowa State alloys. L. Ke1, D. Kukusta1 and V. Antropov11. Ames Laboratory, University, Ames, IA; 4. Lawrence Berkeley National Laboratory, Ames, IA Berkeley, CA; 5. Department of Physics and Astronomy, University of Nebraska, Lincoln, NE; 6. Department of Physics, Rowan University, Glassboro, NJ; 7. Center for Neutron 9:42 Research, NIST, Gaithersburg, MD; 8. Pacific Northwest National 1,2 Laboratory, Richland, WA AF-05. Off-Stoichiometric L10-Ordered FeNi. P. Manchanda , R. Skomski2, L.H. Lewis3 and A. Kashyap1,21. School of Basic Sciences, Indian Institute of Technology, Mandi, himchal pradesh, 10:54 India; 2. Department of Physics and Astronomy and Nebraska Center for Materials and Nanoscience, University of Nebraska, AF-11. Polyol-mediated synthesis, characterization and magnetic Lincoln, NE; 3. Department of Chemical Engineering, properties of core@shell Co@CoFe2O4 nanorods. Northeastern University, Boston, MA J. Piquemal1, K. Aït Atmane1, J. Nelayah2, K. Shinoda3 and C. Ricolleau21. Department of Chemistry, ITODYS, University Paris Diderot, Paris, France; 2. Department of Physics, MPQ, 9:54 University Paris Diderot, Paris, France; 3. Institute of AF-06. Influence of Ball Milling Conditions on the Properties of L10 Multidisciplinary Research for Advanced Materials, University of FePt Nanoparticles Fabricated by a New Green Direct Tohoku, Sendai, Japan Chemical Synthesis Method. X. Hu1, A. Capobianchi2, 3 4 R. Gallagher and G.C. Hadjipanayis 1. Materials Science and 11:06 Engineering, University of Delaware, Newark, DE; 2. 2. Istituto di Struttura della Materia. CNR, Rome, Italy; 3. Mechanical AF-12. High magnetocrystalline anisotropy in oxides with near cubic Engineering, University of Delaware, Newark, DE; 4. Physics and local environments.X. Chen1, D. Parker1, K.P. Ong2, M. Du1 Astronomy, University of Delaware, Newark, DE and D.J. Singh11. ORNL, Oak Ridge, TN; 2. Institute for High Performance Computing, Singapore, Singapore 10:06 11:18 AF-07. Tunable Imprinted Anisotropy and Magnetostrictive AF-13. Perpendicular Magnetic Anisotropy in Epitaxially Strained Properties of Amorphous SmxCo100-x Thin Films. G. Andersson1, F. Magnus1, R. Moubah1, V. Kapaklis1 and Cobalt-Ferrite (001) Thin Films. H. Yanagihara1, Y. Utsumi1, B. Hjörvarsson11. Department of Physics and Astronomy, Uppsala T. Niizeki1, J. Inoue1, E. Kita1, Y. Yamasaki2, H. Nakao2 and University, Uppsala, Sweden K. Koike31. Institute of Applied Physics, University of Tsukuba, Tsukuba, Japan; 2. CMRC and PF, IMSS, KEK, Tsukuba, Japan; 3. Graduate School of Science, Hokkaido University, Sapporo, 10:18 Japan AF-08. Effect of Rapid Thermal Annealing on Thick and Thin Nd-Fe- B films Prepared by Sputtering. N. Gunduz Akdogan1, N.M. Dempsey1 and D. Givord11. Institut Neel, CNRS-UJF, Grenoble, France

10:30 AF-09. Perpendicular magnetic anisotropy of distorted Fe-Co alloy thin films deposited on single crystal substrates. T. Shima1,3, J. Kurian1, U.S. Sharath1, B. Frincu1, L. Alff1 and O. Gutfleisch1,21. Institute for Materials Science, Technische Universität, Darmstadt, Germany; 2. IWKS Group Materials Recycling and Resource Strategy, Fraunhofer ISC, Hanau, Germany; 3. Faculty of Engineering, Tohoku Gakuin University, Tagajo, Japan 30 PROGRAM PROGRAM 31

TUESDAY GOVERNOR’S SQ 16 9:30 MORNING AG-06. Spin reorientation induced by antiferromagnetic coupling. 8:30 M. Ranjbar1,2, R. Sbiaa1,3, R.K. Dumas2, J. Åkerman2,4 and S.N. Piramanayagam11. Data Storage Institute, Agency for Session AG Science, Technology and Research, Singapore, Singapore; 2. ULTRA-THIN FILM MAGNETISM I Department of Physics, University of Gothenburg, Gothenburg, Sweden; 3. Department of Physics, Sultan Qaboos University, Brian Kirby, Chair Muscat, Oman; 4. Materials Physics, School of ICT, Royal Institute of Technology (KTH), Stockholm, Sweden 8:30 AG-01. 5d surface state on Sm1-xGdxAl2 (111), A ferromagnet 9:42 1 1 without magnetization. M. Bersweiler , K. Dumesnil , AG-07. Controllable magnetic interface in FeRh-doped system. C. Le 2 2 1 1 1 P. Lefevre , A. Taleb , D. Pierre , D. Lacour and M. Hehn 1. Graet1,2, T. Charlton5, M. Loving4, M. McLaren3,2, C.J. Kinane5, Institut Jean Lamour, Vandoeuvre-lès-Nancy Cedex, France; 2. D. Alba-Venero5, M.A. De Vries6, R.M. Brydson3, L.H. Lewis4, Synchroton SOLEIL, Gif-sur-Yvette, France S. Langridge5 and C.H. Marrows21. Laboratoire de Magnétisme de Bretagne, Université de Bretagne Occidentale, Brest, France; 8:42 2. School of Physics and Astronomy, University of Leeds, Leeds, United Kingdom; 3. Institute of Materials Research, SPEME, AG-02. Intrinsic spin polarization at the surface of ferrite thin films. University of Leeds, Leeds, United Kingdom; 4. Department of 1,2 2 3 2 A. Pratt , M. Kurahashi , X. Sun and Y. Yamauchi 1. Chemical Engineering, Northeastern University, Boston, MA; 5. International Center for Young Scientists, National Institute for ISIS, Harwell Science and Innovation Campus, Science and Materials Science, Tsukuba, Ibaraki, Japan; 2. National Institute Technology Facilities Council, Rutherford Appleton Laboratory, for Materials Science, Tsukuba, Ibaraki, Japan; 3. University of Didcot, Oxon, United Kingdom; 6. School of Chemistry, Science and Technology of China, Hefei, Anhui, China University of Edinburgh, Edinburgh, United Kingdom

8:54 9:54 AG-03. Preparation of epitaxial NiFe(111)/AlOx ultrathin bilayer AG-08. Magnetic properties of ultra-thin Co layers in Co/Ru 1,2 structures for a high-efficiency spin injector. S. MItani , multilayers. A. Zamani1, M. Arora2, T. Mckinnon2, B. Heinrich2, 1,2 1 J. Koo and H. Sukegawa 1. National Institute for Materials O. Mryasov3, P. Jonsson1 and E. Girt21. Department of Physics Science, Tsukuba, Japan; 2. Graduate School of Pure and Applied and Astronomy, Uppsala University, Uppsala, Sweden; 2. Sciences, University of Tsukuba, Tsukuba, Japan Department of Physics, Simon Fraser University, Burnaby, BC, Canada; 3. Department of Physics, University of Alabama, 9:06 Tuscaloosa, AL AG-04. Simple fabrication of L1 -ordered FeNi thin films by co- 0 10:06 sputtering and post-annealing. M. Mizuguchi1, T. Tashiro1, 1 2 2 2 T. Kojima , T. Koganezawa , T. Ohtsuki , M. Kotsugi and AG-09. Effect of MgO capping thickness on anisotropy of CoFeB on 1 K. Takanashi 1. Institute for Materials Research, Sendai, Miyagi, Ru and Ta underlayers. S. Yang1, K. Shen1, S. Huang1, Japan; 2. Japan Synchrotron Radiation Research Institute, Sayo- C. Chien1, J. Shyu1, Y. Wang1 and D. Deng11. Electronics and cho, Hyogo, Japan Opto-Electronics Research Lab. (EOL), ndustrial Technology Research Institute (ITRI), Hsinchu, Taiwan 9:18 10:18 AG-05. Magnetoluminescence Properties of OLED with Fe/MgO(001) Anode: Explore carrier behaviors in hybrid multilayers. AG-10. High thermal stability and low damping constant of 1 2 1 1 N. Lee , E. Ito , Y. Bae and T. Kim 1. Department of Physics, perpendicular CoFeB/MgO bilayer.D. Wang1, L. Wang1, EWHA WOMANS UNIV., Seoul, Republic of Korea; 2. Flucto- S. Lai1, K. Huang1, C. Chien2, D. Ellsworth3, Y. Wang2, M. Wu3 Order Functions Research Team, RIKEN Advanced Science and C. Lai11. Materials Science and Engineering, National Tsing Institute, Wako, Japan Hua University, Hsinchu, Taiwan; 2. Electronics and Optoelectronics Research Laboratories, Industrial Technology Research Institute, Chutung, Taiwan; 3. Department of Physics, Colorado State University, Fort Collins, CO 32 PROGRAM PROGRAM 33

10:30 8:42 AG-11. Interface magnetism of Ta/CoFeB/MgO heterostructures AH-02. Exchange-dominated eigenmodes in sub-100 nm permalloy investigated by X-ray magnetic circular dichroism. T. Ueno1,2, dots: a micromagnetic study at finite temperature. N. Inami2, Y. Takeichi2, J. Sinha1, S. Mitani1, M. Hayashi1 and G. Carlotti1, M. Madami1, G. Gubbiotti2 and S. Tacchi21. K. Ono21. National Institute for Materials Science, Tsukuba, Dipartimento di Fisica, University of Perugia, Perugia, Italy; 2. Japan; 2. Institute of Materials Structure Science, High Energy Istituto Officina dei Materiali (IOM-CNR), Consiglio Nazionale Accelerator Research Organization, Tsukuba, Japan delle Riicerche, Perugia, Italy

10:42 8:54 AG-12. Low temperatures crystallization of Ta-CoFeB-MgO ultra- AH-03. Micromagnetic simulations of the dynamics of three thin films with perpendicular anisotropy by using He ion interacting magnetic vortices in a triangular arrangement. irradiation.I. Barisik1, T. Devolder1, S. Eimer1, N. Vernier1, M.A. Asmat-Uceda1, X.M. Cheng2, X. Wang2, D.J. Keavney3, J. Adam1, K. Garcia1, B. Ockert2, A. Lamperti3, R. Mantovan3 and D.J. Clarke4,5, O. Tchernyshyov4 and K.S. Buchanan11. D. Ravelosona1,41. University of Paris Sud, Orsay, France; 2. Department of Physics, Colorado State University, Fort Collins, Singulus, Kahl, Germany; 3. CNR-IMM MDM laboratory, Agrate, CO; 2. Department of Physics, Bryn Mawr College, Bryn Mawr, Italy; 4. SILTENE technologies, Orsay, France PA; 3. Advanced Photon Source, Argonne National Laboratory, Argonne, IL; 4. Department of Physics and Astronomy, Johns Hopkins University, Baltimore, MD; 5. Department of Physics 10:54 and Astronomy, University of California, Riverside, CA AG-13. Quasi-static and dynamic magnetic properties of obliquely 1,2 2 1,2 sputtered CoFe films. S. Paul , M. Buchmeier , T. Mewes 9:06 and G. Mankey1,21. Physics Department, The University of Alabama, Tuscaloosa, AL; 2. MINT Center, The University of AH-04. Energy Barrier for Thermally Activated Magnetization Alabama, Tuscaloosa, AL Reversal in Nanodisks with Perpendicular Magnetic Anisotropy. G.D. Chaves-O’Flynn1, J.Z. Sun2 and A.D. Kent31. Mathematical Sciences, New Jersey Institute of Technology, 11:06 Newark, NJ; 2. IBM T. J. Watson Research Center, Yorktown AG-14. Characterization of metastable crystal structure for CoPt- Heights, NY; 3. Dept. of Physics, New York University, New York, alloy thin film. M. Ohtake1, D. Suzuki1 and M. Futamoto11. NY Faculty of Science and Engineering, Chuo University, Tokyo, Japan 9:18 AH-05. Current induced magnetization switching hysteresis loops - 11:18 micromagnetic modeling and experiment. M. Frankowski1, AG-15. Magneto-electronic and optical properties of Fe-N films. M. Czapkiewicz1, W. Skowronski1 and T. Stobiecki11. O.N. Mryasov1,2, S. Faleev2, S. Okatov2, X. Li3 and J. Wang31. Department of Electronics, AGH University of Science and Physics and Astronomy, University of Alabama, Tuscaloosa, AL; Technology, Krakow, Poland 2. MINT Center, University of Alabama, Tuscaloosa, AL; 3. MINT Center & Electrical and Computer Engineering Department,, 9:30 University of Minnesota, Minneapolis, MN AH-06. Analysis of microwave assisted switching of exchange spring media by circularly polarized magnetic fields.R. Tayade1, A. Pasko1, F. Mazaleyrat1, C. Serpico2 and M. LoBue11. SATIE, ENS CACHAN, CNRS, UniverSud, Cachan, France; 2. TUESDAY GOVERNOR’S SQ 12 Dipartimento di Ingegneria Elettrica, Universitá di Napoli MORNING Federico II, Napoli, Italy 8:30 9:42 Session AH AH-07. A numerical approach to incorporate intrinsic material MICROMAGNETIC MODELING I defects in micromagnetic simulations. J. Leliaert1,2, B. Van de Olle Heinonen, Chair Wiele1, A. Vansteenkiste2, L. Laurson3, G. Durin4,5, B. Van Waeyenberge2 and L. Dupré11. Department of Electrical Energy, Systems and Automation, Ghent University, Ghent, Belgium; 2. 8:30 Department of Solid State Physics, Ghent University, Gent, AH-01. Self-modulated solitons excited in an STNO.V. Puliafito1, Belgium; 3. Department of Applied Physics, Aalto University, B. Azzerboni1 and G. Finocchio11. Department of Electronic Espoo, Finland; 4. Istituto Nazionale di Ricerca Metrologica Engineering, Industrial Chemistry and Engineering, University of Torino, Turin, Italy; 5. ISI Foundation, Turin, Italy Messina, Messina, Italy 34 PROGRAM PROGRAM 35

9:54 TUESDAY EXHIBIT HALL AH-08. Magnetic properties of Fe20 Ni80 antidots: Pore size and MORNING array disorder. J.L. Palma1, C. Gallardo1, L. Spinu2, 9:30 J.M. Vargas2, L.S. Dorneles3, J.C. Denardin1,4 and J. Escrig1,41. Física, Universidad de Santiago de Chile, Santiago, Chile; 2. Session AP Advanced Material Research institute (AMRI) and Department of MULTILAYERS AND THIN FILMS Physics, University of New Orleans, New Orleans, LA; 3. Departamento de Física, Universidade Federal de Santa María (Poster Session) UFSM, Santa María, RS, Brazil; 4. Center for the Develpment of Joo-Von Kim, Chair Nanoscience and Nanotechnology, CEDENNA, Santiago, Metropolitana, Chile AP-01. Sputtering Perpendicular Magnetic Anisotropy L11CoPt Thin Film on Glass substrate at Room Temperature. A. Sun1, 10:06 C. Huang1, H. Wu1, F. Yuan2 and J. Hsu31. Department of Chemical Engineering & Materials Science, Yuan Ze University, AH-09. Vortex state in ferromagnetic nanoparticles. D. Betto1, S. Sen1, Taoyuan, Taiwan; 2. iSentek Ltd., Advanced Sensor Laboratory, M. Venkatesan1, S. Mosivand1 and J. Coey11. Physics, Trinity Taipei, Taiwan; 3. Department of Physics, National Taiwan College Dublin, Dublin, Ireland Unviersity, Taipei, Taiwan

10:18 AP-02. Ordered phase formation in Co50Pt50-alloy single-layer and AH-10. Creating an artificial two-dimensional Skyrmion crystal by Co/Pt multilayer films epitaxially grown on MgO(111) nano-patterning. (Invited) L. Sun1, R. Cao1, B. Miao1, Z. Feng1, substrates. D. Suzuki1, M. Ohtake1, F. Kirino2 and B. You1, D. Wu1, W. Zhang1, A. Hu1 and H. Ding11. National M. Futamoto11. Faculty of Science and Engineering, Chuo Laboratory of Solid State Microsctructures and Department of University, Tokyo, Japan; 2. Graduate School of Fine Arts, Tokyo Physics, Nanjing University, Nanjing, Jiangsu, China University of the Arts, Tokyo, Japan

10:54 AP-03. Interlayer Coupling and Magnetoresistance Behaviors of

[Co/Pd]4/Co/Ru/[Co/Pd]2 Pseudo-spin-valve Multilayers. AH-11. Micromagnetic Study of Exchange Coupling and X. Liu1, J. Ding1, G.N. Kakazei1 and A.O. Adeyeye11. Electrical Demagnetization-driven effects in Magnetic Tunnel Junctions. 1 2 1 3 and Computer Engineering, National University of Singapore, A. Baker , C. Davies , A. Figueroa-Garcia , T. Hesjedal and Singapore, Singapore G. van der Laan11. Magnetic Spectroscopy Group, Diamond Light Source, Chilton, United Kingdom; 2. Department of Physics and 1 Astronomy, University of Exeter, Exeter, United Kingdom; 3. AP-04. Controlling magnetic anisotropy Co/Ni multilayers. M. Arora , 1 2 1 1 Clarendon Laboratory, University of Oxford, Oxford, United T. McKinnon , A. Zamani , E. Montoya , B. Heinrich and 1 Kingdom E. Girt 1. Department of Physics, Simon Fraser University, Burnaby, BC, Canada; 2. Department of Physics and Astronomy, Uppsala University, Uppsala, Sweden 11:06 AH-12. Effect of interlayer exchange coupling parameter on switching AP-05. Effects of Ni addition in FeOx on Thermal Endurance of time, critical current density and energy barrier in [Co/Pt Biquadratic Coupling. K. Huang1, P. Wang1 and C. Lai11. 1,2 multilayers]/Ta/CoFeB composite free layer. A. Singh , National Tsing Hua University, Hsinchu, Taiwan S. Gupta2,3, O.N. Mryasov1,2, M. Escobar4 and V. Lomakin41. Physics, University of Alabama, Tuscaloosa, AL; 2. MINT Center, University of Alabama, Tuscaloosa, AL; 3. Metallurgical and AP-06. Precessional magnetization dynamics for Fe/Mn-Ga exchange Materials Engineering, University of Alabama, Tuscaloosa, AL; 4. coupled bilayer films with a large perpendicular magnetic 1 1 2 1,2 CMRR, University of California, San Diego, CA anisotropy. S. Mizukami , T. Kubota , S. Iihama , R. Ranjbar , Q. Ma1, X. Zhang1, Y. Ando2 and T. Miyazaki11. WPI-AIMR, Tohoku University, Sendai, Japan; 2. Dept. of Appl. Phys., Tohoku 11:18 University, Sendai, Japan AH-13. Magnetic shunt as high frequency field generator. K. Rivkin1, M. Benakli1 and H. Yin11. Seagate Technology, Edina, MN 36 PROGRAM PROGRAM 37

AP-07. Perpendicular magnetic anisotropy in AP-14. (001)-textured polycrystalline current-perpendicular-to-plane 2,1 MgO/CoFeB/Ta/[Co/Pd]n structures. Y. Chang , A. Canizo- pseudo spin-valves using full Heusler alloy Cabrera3,1, V. Garcia-Vazquez4, Y. Chang5 and T. Wu61. Taiwan Co2Fe(Ga0.5Ge0.5). Y. Du 1,2, B. Varaprasad2, T. Furubayashi2, SPIN Research Center, National Yunlin University of Science and Y. Takahashi2 and K. Hono2,11. Graduate School of Pure and Technology, Douliu,Yunlin, Taiwan; 2. Graduate School of Applied Sciences, University of Tsukuba, Tsukuba, Japan; 2. Engineering Sci. & Tech., National Yunlin University of Science National Institute for Materials Science, Tsukuba, Japan and Technology, Douliu,Yunlin, Taiwan; 3. Universidad del Valle de Puebla, Puebla, Pue, Mexico; 4. Instituto de Física Luis Rivera AP-15. GMR magnetoresistance enhancement of spin valve sensor by Terrazas, Benemérita Universidad Autónoma de Puebla, Puebla, magnetic annealing. T. Kuo1, Y. Chen1 and Z. Wei21. Institute of Pue, Mexico; 5. Department and Institute of Electronic NanoEngineering and MicroSystems, National Tsing Hua Engineering, National Yunlin University of Science and University, Hsinchu, Taiwan; 2. Department of Power Mechanical Technology, Douliu,Yunlin, Taiwan; 6. Graduate School of Engineering, National Tsing Hua University, Hsinchu, Taiwan, Materials Science, National Yunlin University of Science and Hsinchu, Taiwan Technology, Douliu,Yunlin, Taiwan

AP-16. Interaction in ferromagnetic thin film across an AP-08. The bow-tie shape hysteresis loops induced by magnetostatic antiferromagnetic layer. X. Tang1, W. Du1, H. Su1 and energy in [Ta/CoFeB/MgO] multilayers with perpendicular N H. Zhang11. State Key Laboratory of Electronic Thin Films and anisotropy.L. Hao1, J. Cao1, M. Liu1, H. Dang1, T. Jin1, Integrated Devices, University of Electronic Science and Y. Wang1, D. Wu1, F. Wei1 and D. Wei21. Key Laboratory for Technology of China, Chengdu, Sichuan, China Magnetism and Magnetic Materials of the Ministry of Education, Lanzhou University, Lanzhou 730000, P.R. China, Lanzhou, Gansu, China; 2. Key laboratory for Advanced Materials Ministry AP-17. Strongly enhanced interfacial specific resistance in of Education, Tsinghua University, Beijing 100084, China, FeCo/Ag/FeCo trilayer with thin Fe insertion layer and Beijing, Beijing, China effective way for large CPP-GMR output. J. Jung1, Z. Jin1, Y. Shiokawa1, B. Lao1 and M. Sahashi11. Electronic engineering, Tohoku University, Sendai, Japan AP-09. Spin reorientation transition in Co/Au multilayers. J. Quispe- Marcatoma1,3, M. de Sousa2, F. Pelegrini2, B. Pandey4 and E. Baggio-Saitovitch11. Fisica Experimental (EXP), Centro Brasileiro de Pesquisas Físicas, Rio de Janeiro, Brazil; 2. Instituto de Física, Universidade Federal de Goiás, Goiânia, Brazil; 3. Facultad de Ciencias Físicas, Universidad Nacional TUESDAY EXHIBIT HALL Mayor de San Marcos, Lima, Peru; 4. Applied Physics, Symbiosis MORNING Institute of Technology, Pune, India 9:30

AP-10. Magnetic and Structural Origin of Perpendicular Magnetic Session AQ Anisotropy of Fe/Tb and Fe/Gd Multilayers: A Comparative FRUSTRATION AND LOW-DIMENSIONAL Study. A. Chowdhury11. Physics, University of Alaska Fairbanks, Fairbanks, AK SYSTEMS (Poster Session) AP-11. Magnons in one-dimensional k component Fibonacci Alexandru Stancu, Chair structures.M.S. Vasconcelos1 and C.H. Costa21. Escola de Ciencias e Tecnologia, Universidade Federal do Rio Grande do AQ-01. Magnetization plateau of dipolar spin ice on a kagome Norte, Natal, RN, Brazil; 2. Departamento de Física, lattice.Y. Xie1, Y. Wang1, Z. Yan1 and J. Liu11. Department of Universidade Federal do Rio Grande do Norte, Natal, RN, Brazil Physics, Nanjing University, Nanjing, Jiangsu, China

AP-12. Growth and Characterization of Pt-protected Gd5Si4 thin AQ-02. Grain boundary effects in geometrically frustrated spin chain 1,2 2 2 films. R.L. Hadimani , Y. Mudryk , T.E. Prost , Ca Co O P.J. Lampen1, N. Bingham1, M. Phan1, H. Yi2, 2,3 2,3 1,2 3 2 6 V.K. Pecharsky , K.A. Gschneidner and D.C. Jiles 1. S. Cheong2 and H. Srikanth11. Department of Physics, University Department of Electrical and Computer Engineering, Iowa State of South Florida, Tampa, FL; 2. Rutgers Center for Emergent University, Ames, IA; 2. Ames Laboratory,, US Dept. of Energy, Materials, Rutgers University, New Brunswick, NJ Ames, IA; 3. Department of Materials Science and Engineering, Iowa State University, Ames, IA AQ-03. Terbium induced glassy magnetism in La,Ca-based cobaltites. M. Marysko1, J. Hejtmanek1, Z. Jirak1, O. Kaman1 and 1 AP-13. Ultra-thin L10-FePt for perpendicular anisotropy L10- K. Knizek 1. Institute of Physics ASCR, Praha 6, Czech Republic 1,2 2 FePt/Ag/[Co3Pd8]30 pseudo spin valves. P. Ho , G. Han , K. He3, G. Chow1 and J. Chen11. NUS, Singapore, Singapore; 2. A*STAR Data Storage Institute, Singapore, Singapore; 3. China University of Geosciences, Wuhan, China 38 PROGRAM PROGRAM 39

AQ-04. Observation of Ten-Fold Rotational Symmetry in Five-Fold AQ-13. Low-temperature thermal conductivity of antiferromagnetic Artificial Quasicrystal Arrays. B.W. Farmer1, V. Bhat1, S=1/2 chain material CuCl_{2}-2((CH_{3})_{2}SO). W. Ke 1, J. Woods1, T. Hastings1, L. De Long1, J. Sklenar2 and J. Shi2, F. Zhang1, Z. Zhao1, C. Fan1, X. Zhao3 and X. Sun11. J. Ketterson21. Physics and Astronomy, University of Kentucky, National Laboratory for Physical Sciences at Microscale, Lexington, KY; 2. Physics and Astronomy, Northwestern University of Science and Technology of China, Hefei, Anhui, University, Evanston, IL China; 2. Department of Physics, University of Science and Technology of China, Hefei, Anhui, China; 3. School of Physical Sciences, University of Science and Technology of China, Hefei, AQ-05. Withdrawn Anhui, China

AQ-06. Evidence of a cluster glass-like behavior in Fe-doped ZnO AQ-14. Withdrawn nanoparticles. J.E. Ramos1, M. Montero - Muñoz1, J.E. Rodríguez - Páez2 and J.H. Coaquira11. Institute of Physics, University of Brasilia, Brasilia, DF, Brazil; 2. Department of AQ-15. Absence of Exchange Interaction between Localized Magnetic Physics, University of Cauca, Popayán, Cauca, Colombia Moments and Conduction-electrons in diluted Er3+ Gold- nanoparticles. G.G. Lesseux1, W.A. Iwamoto1, A.F. Garcia- Flores2, R.R. Urbano1 and C. Rettori1,21. Universidade Estadual AQ-07. Re-entrant spinglass behaviour in the quaternary Heusler de Campinas, Campinas, São Paulo, Brazil; 2. Universidade alloy Cu Mn Fe Al. V. Buchepalli1 and H. Narayanan11. 2 0.75 0.25 Federal do ABC, Santo André, Brazil Advanced Magnetic Materials Laboratory, Department of Physics, Indian Institute of Technology Madras, Chennai, Tamilnadu, India AQ-16. Design of Carbon-based Materials with Strong Ferromagnetic Coupling. N.A. Tuan1,2 and T.V. Nguyen11. Faculty of Physics, Hanoi University of Science, Vietnam National University, Hanoi, AQ-08. Effect of Size Reduction on the Magnetic Ordering in Viet Nam; 2. School of Materials Science, Japan Advanced Bi0.2Sr0.8MnO3. G. Singh1 and S.V. Bhat11. Department of Institute of Science and Technology, Nomi, Ishikawa, Japan Physics, Indian Institute of Science, Bangalore, India

AQ-09. Static and dynamic magnetic properties of hollow spherical γ 1 1 1 Fe2O3 nanoparticles. H. Khurshid , S. Chandra , M. Phan , P. Mukherjee1 and H. Srikanth11. Department of Physics, TUESDAY EXHIBIT HALL University of South Florida, Tampa, FL MORNING 9:30

AQ-10. Low temperature spin dynamics in Cr7Ni-Cu-Cr7Ni coupled molecular rings. L. Bordonali1,5, C.M. Casadei1,5, E. Garlatti2,3, Session AR Y. Furukawa4,5, F. Borsa1,5, A. Lascialfari2,6, G. Timco7 and R.E. Winpenny71. Department of Physics, Università degli Studi SOFT MAGNETS: AMORPHOUS AND di Pavia, Pavia, Italy; 2. Department of Physics, Università degli NANOCOMPOSITE I Studi di Milano, Milano, Italy; 3. Department of Physics, (Poster Session) Università di Parma, Parma, Italy; 4. Department of Physics and Astronomy, Iowa State University, Ames, IA; 5. AmesLab, Ames, Ivan Skorvanek, Chair IA; 6. Consorzio INSTM, Firenze, Italy; 7. The Lewis Magnetism Laboratory, University of Manchester, Manchester, United AR-01. Superior high temperature soft magnetic properties of Si-rich Kingdom 1 nanocrystalline (Fe0.9Co0.1)74.5Nb2Si17.5B5Cu1 alloy.W. Li-Xia , Z. Wang1, W. Jia1 and Z. Hao11. Tianjin University, Tianjin, AQ-11. Magnetocaloric effect in a mixed-spin Ising-Heisenberg Tianjin, China diamond chain with various types of spin interactions. Y. Qi 1 and A. Du11. College of Sciences, Northeastern University, AR-02. Sintered magnetic cores of high Bs Fe84.3Si4B8P3Cu0.7 nano- Shenyang, Liaoning, China crystalline alloy with a lamellar microstructure. Y. Zhang1,2, P. Sharma1,2 and A. Makino1,21. Cooperative Research and AQ-12. Magnetic and Dielectric Properties of One-Dimensional Array Development Center for Advanced Materials, Institute for of S=1/2 Linear Trimer System Na2Cu3Ge4O12. Y. Yasui1,2, Materials Research, Tohoku University, Sendai, Miyagi, Japan; 2. Y. Kawamura2, Y. Kobayashi2 and M. Sato2,31. Physics, Meiji Research and Development Center for Ultra High Efficiency University, Kawasaki, Japan; 2. Physics, Nagoya University, Nano-crystalline Soft Magnetic Materials, Institute for Materials Nagoya, Japan; 3. Comprehensive Research Organization for Sci. Research, Tohoku University, Sendai, Miyagi, Japan and Soc., Tokai, Japan AR-03. Effect of crystalline size and distribution on soft magnetic properties of FePBNbCr amorphous alloy. J. Lee1,2, D. Kim2 and H. Kim11. Korea Institute of Industrial Technology, Incheon metropolitan, Republic of Korea; 2. Younsei university, Seoul, Republic of Korea 40 PROGRAM PROGRAM 41

AR-04. Modulation of unidirectional anisotropy for Co-based AR-12. Long-range ferromagnetism in Gd53Al24Co20Zr3 amorphous amorphous ribbons by longitudinal pulse field. J. He1, microwires: Role of structural disorder. A. Biswas1, P. Zhang1,4, Y. Jing1,2, J. An1 and Z. Xia11. Division of Functional Material Y.Y. Yu 1, N.S. Bingham1, H. Wang2, F. Qin3, H.X. Peng3, Research, Central Iron & Steel Research Institute, Beijing, China; J.F. Sun2, S.C. Yu4, V. Franco5, H. Srikanth1 and M. Phan11. 2. School of Mathematics, Physics and Biological Engineering, Department of Physics, University of South Florida, Tampa, FL; Inner Mongolia University of Science and Technology, Baotou, 2. School of Materials Science and Engineering, Harbin Institute China of Technology, Harbin, China; 3. Advanced Composite Center for Innovation and Science, University of Bristol, Bristol, United Kingdom; 4. Department of Physics, Chungbuk National AR-05. Intrinsic domain wall pinning in rapidly solidified amorphous University, Cheongju, Republic of Korea; 5. Dpto. Fisica de la nanowires. T.A. Ovari1 and H. Chiriac11. National Institute of Materia Condensada, Universidad de Sevilla, Sevilla, Spain Research and Development for Technical Physics, Iasi, Romania

AR-13. Comparative Investigation on AC Inductors according to AR-06. Effects of the easy axis direction on magnetoimpedance Magnetic Core Materials for Performance Improvement of properties of thin films with uniaxial anisotropy. H. Kikuchi1, LLC Resonant DC-DC Converter in Auxiliary Power Supply Y. Takahashi1, K. Takahashi1, T. Nakai2, S. Hashi3 and of Magnetic Levitation Vehicles. Y. Park1, K. Lee2, S. Jang1, K. Ishiyama31. Faculty of Engineering, Iwate University, M. Koo1 and J. Choi11. Chungnam National University, Daejoen, Morioka, Iwate, Japan; 2. Industrial Technology Institute, Miyagi Republic of Korea; 2. Daejeon Metropolitan Express Transit Prefectural Government, Sendai, Miyagi, Japan; 3. Research Corporation, Daejeon, Republic of Korea Institute of Electrical Communication, Tohoku University, Sendai, Miyagi, Japan AR-14. Geometric Design and Performance Computation of SRM with Amorphous alloys core for Home Appliance Applications. AR-07. Magneto-impedance sensor for quasi-noncontact monitoring H. Liu1 and Y. Chen11. School of Electrical Engineering, Beijing of breathing, pulse rate and activity status. S. Corodeanu1, Jiaotong University, Beijing, China H. Chiriac1, L. Radulescu2 and N. Lupu11. National Institute of Research & Development for Technical Physics, Iasi, Romania; 2. University of Medicine and Pharmacy “Gr.T.Popa”, Iasi, AR-15. Nanocrystalline Ribbons for Energy Harvesting Romania Applications.H. Chiriac1, M. Tibu1, N. Lupu1, I. Skorvanek2 and A.T. Ovari11. National Institute of Research and Development for Technical Physics, Iasi, Romania; 2. Institute of Experimental AR-08. Effect of composite origin on magnetic properties of glass- Physics – Slovak Academy of Sciences, Kosice, Slovakia coated microwires. A.P. Zhukov1,2, E. Zamiatkina3, E. Shuvaeva3, S. Kaloshkin3, M. Churyukanova3 and V. Zhukova11. Phys. Mater., UPV/EHU, San Sebastián, Spain; 2. IKERBASQUE, Basque Foundation for Science, Bilbao, Spain; 3. Centre of Composite Materials, National University of Science and Technology «MISIS», Moscow, Russian Federation TUESDAY EXHIBIT HALL MORNING AR-09. Combined current-modulation annealing induced pronounced 9:30 enhancement of GMI effect of Co-rich amorphous microwires. J. Liu1,2, D. Chen1, F. Qin3, H. Wang1, H. Shen1, D. Xing1 and Session AS J. Sun11. School of Materials Science and Engineering, Harbin MAGNETIC SENSORS (NOT FOR Institute of Technology, Harbin, Heilongjiang, China; 2. School of Materials Science and Engineering, Inner Mongolia University of RECORDING) Technology, Hohhot, Inner Mongolia, China; 3. National Institute (Poster Session) for Material Science, Tsukuba, Japan Filipe Cardoso, Chair

AR-10. Tailoring magnetic anisotropy in Co100-xNix nanowire array. AS-01. Design and implementation of a spin-valve sensor for a single 1,2 2 2 2 3 A. Pereira , A.P. Espejo , C. Gallardo , J. Briones , L. Vivas , magnetic nanoparticle detection. Y. Liang1, A. Kolhatkar2, 3 2 2 M. Vazquez , J. Escrig and J.C. Denardin 1. Metalurgia, D. Litvinov1,3 and R.T. Lee1,21. Dept. of Chemical and Universidad de Santiago de Chile, Santiago, Santiago, Chile; 2. Biomolecular Engineering, University of Houston, Houston, TX; Fisica, Universidad de Santiago de Chile, Santiago, Santiago, 2. Dept. of Chemistry, University of Houston, Houston, TX; 3. Chile; 3. CSIC, Instituto de Ciencia de Materiales de Madrid, Dept. of Electrical and Computer Engineering, University of Madrid, Madrid, Spain Houston, Houston, TX

AR-11. Synthesis and Characterization of FeCo Nanowires With High Coercivity. K.H. Gandha1, P. Tsai1, Q. Zhang1, N. Poudyal1 and J. Liu11. Department of Physics, The University of Texas at Arlington, Arlington, TX 42 PROGRAM PROGRAM 43

AS-02. Sensitivity and Sensing range Controllable STT-MTJ Field AS-10. Magnetic tunnel junctions for highly sensitive magnetic field Sensor. S. Kim1,2, M. Seo1, K. Lee2,3 and S. Park11. Division of sensor by using CoFeB sensing layer capped with MgO film. Materials Science, Korea Basic Science Institute, Daejeon, T. Takenaga1, Y. Tsuzaki1, C. Yoshida1, Y. Yamazaki1, A. Hatada1, Republic of Korea; 2. Department of Materials Science and M. Nakabayashi1, Y. Iba1, A. Takahashi1, H. Noshiro1, Engineering, Korea University, Seoul, Republic of Korea; 3. KU- K. Tsunoda1, M. Aoki1, T. Furukawa1, H. Fukumoto1 and KIST Graduate School of Converging Science and Technology, T. Sugii11. Low-power Electronics Association and Project Korea University, Seoul, Republic of Korea (LEAP), Tsukuba, Japan

AS-03. An in-depth noise model for GMR current sensors for circuit AS-11. Improved Frequency Response of ME Sensors by Using design and CMOS integration. A. Roldan1, J. Roldán1, C. Reig2, Closed Loop Feedback of AC Modulation technology. Y. Zhu1, S. Cardoso3,4, F. Cardoso3 and P. Freitas3,41. Electronics and X. Yang1, J. Ouyang1, S. Chen1, B. Tong1 and T. Zhang11. School Computer Technology, University of Granada, Granada, of Optical and Electronic Information, HuaZhong University of Granada, Spain; 2. Electronic Engineering, University of Science and Technology, Wuhan, Hubei, China Valencia, Burjassot, Valencia, Spain; 3. Instituto de Engenharia de Sistemas e Computadores Microsistemas e Nanotecnologias, AS-12. A novel dc magnetic field sensor based on the turning of Lisbon, Lisbon, Portugal; 4. International Iberian elastic modulus in magnetostrictive/piezoelectric composite. Nanotechnology Laboratory, Braga, Braga, Portugal L. Zhang1, C. Leung1 and S. Or11. Electrical Engineering, The Hong Kong Polytechnic University, Kowloon, Hong Kong AS-04. Modelling of micro-Hall sensors for magnetization imaging. A. Manzin1 and V. Nabaei1,21. Electromagnetics Division, Istituto AS-13. High-sensitivity laminate magnetoelectric sensors without Nazionale di Ricerca Metrologica (INRIM), Torino, Italy; 2. magnetic bias in composite of positive/negative rare-earth iron Dipartimento Energia, Politecnico di Torino, Torino, Italy alloys and piezoelectric single crystals.J. Zhang1, P. Li 1, Y. Wen 1, W. He1, J. Yang1, M. Li1, A. Yang1, C. Lu1 and W. Li11. AS-05. Enhanced sensitivity in magnetoelectric current-sensing Research Center of Sensors and Instruments, College of devices with frequency up-conversion mechanism by Optoelectronic Engineering, Chongqing University, Chongqing, modulating the magnetostrictive strain.J. Zhang1, P. Li 1, China Y. Wen 1, W. He1, J. Yang1, A. Yang1, C. Lu1 and W. Li11. Research Center of Sensors and Instruments, College of Optoelectronic AS-14. 3D integrated magnetic sensor.M. Aurino1, Y. Hadj Larbi1, Engineering, Chongqing University, Chongqing, China P. Sabon1, S. Bandiera2, S. Auffret1, L. Prejbeanu1 and G. Gaudin11. SPINTEC (CNRS/CEA) URA 2512, Grenoble, AS-06. A vibration energy harvester using magnet/piezoelectric France; 2. Crocus Technology, Grenoble, France composite transducer. J. Qiu1, H. Chen1, Y. Wen1, P. Li1, J. Yang1 and W. Li21. Department of Optoelectronic Engineering, AS-15. Biomolecular detection and capture in wavy ferromagnetic Chongqing University, Chongqing, Chongqing, China; 2. College nanostructure. H. Huang1, K. Liao1 and Z. Wei11. Department of of Engineering, University of California, Davis, Davis, CA Power Mechanical Engineering National Tsing Hua University, Hsinchu, Taiwan AS-07. Analysis of Thin-Film MI sensor using the Variations in Impedance and the Magnetic Domain Structure. J. Shin1, AS-16. Optimization Design of A Leakage Current Sensor for Y. Miwa1, S. Kim1, S. Hashi1 and K. Ishiyama11. Research Photovoltaic System Using multilayer GMR material. Institute of Electrical Communication, Tohoku University, Sendai, X. Yang1, C. Xie1, Y. Li1 and Y. Wang11. Province-Ministry Joint Japan Key Laboratory of Electromagnetic Field and Electrical Apparatus Reliability, Hebei University of Technology, Tianjin, AS-08. Ultra-Sensitive Magnetic Field Sensor.M. Kavaldzhiev1, China P. Sabon1, D. Le Roy2, N. Dempsey2, C. Cavoit3, C. Baraduc1, L. Prejbeanu1 and B. Diény11. SPINTEC, Grenoble, France; 2. Institut Néel, Grenoble, France; 3. LPC2E, Orléans, France

AS-09. Small aspect ratio tunnel junction sensors with 120 nm critical dimensions for high resolution magnetic imaging. D.C. Leitao1, A.V. Silva1,2, Z. Hou1, H. Lv1,2, R. Ferreira3, E. Paz3, S. Cardoso1,2 and P.P. Freitas1,21. INESC-MN, Lisboa, Portugal; 2. IST-Instituto Superior Técnico, Universidade Técnica de Lisboa, Lisboa, Portugal; 3. INL-International Iberian Nanotechnology Laboratory, Braga, Portugal 44 PROGRAM PROGRAM 45

TUESDAY EXHIBIT HALL AT-07. Optical and magneto-optical properties of Co doped CeO2-δ films. M. Veis1, M. Kucera1, M. Zahradnik1, R. Antos1, J. Mistrik2, MORNING 3 3 3 3 9:30 L. Bi , H. Kim , G.F. Dionne and C.A. Ross 1. Institute of Physics, Charles University in Prague, Prague, Czech Republic; 2. Department of Physics, University of Pardubice, Pardubice, Session AT Czech Republic; 3. Department of Material Science and MAGNETO-OPTIC AND NEW MAGNETIC Engineering, Massachusetts Institute of Technology, Cambridge, MATERIALS I MA (Poster Session) AT-08. Magneto-Optical Properties of a Ferronematic Colloid. Paulo Morais, Co-Chair E.C. Economou1, Y. Garbovskiy1, A. Glushchenko1, A. Shiva2, Kaizhong Gao, Co-Chair J.B. Wiley2, L.M. Malkinski3 and Z. Celinski11. Center for Magnetism and Magnetic Nanostructures, UCCS, Colorado AT-01. Magnetoplasmonic Properties of Co/Au Nanostructures. Springs, CO; 2. Department of Chemistry and the Advanced C. Rizal1,21. Chemistry, University of Victoria, Victoria, BC, Materials Research Institute, UNO, New Orleans, LA; 3. Canada; 2. Physics and Astronomy, University of Victoria, Department of Physics and the Advanced Materials Research Victoria, BC, Canada Institute, UNO, New Orleans, LA

AT-09. Magneto-optical imaging using magnetophotonic crystals. AT-02. Enhancement of longitudinal magneto-optical Kerr effect in 1 1 1 1 1,2 1 R. Hashimoto , T. Yonezawa , K. Sakaguchi , H. Takagi and HfO2/Co/HfO2/Al/silicon thin films. S. Zhang , S. Tang , 1 J. Gao1, W. Xia1, Y. Tang1 and Y. Du11. Physics Department, M. Inoue 1. Department of Electrical and Electronic Information National Laboratory of Solid State Microstructure of Nanjing Engineering, Toyohashi University of Technology, Toyohashi, University, Nanjing, Jiangsu, China; 2. School of Science, Aichi, Japan Institute of Condensed Matter Physics of Linyi University, Linyi, Shandong, China AT-10. Low-frequency magnetic susceptibility and photoelectric

properties of Glass/Fe40Pd40B20(XÅ)/ZnO(500Å) and 1 1 AT-03. Fano resonance and Kerr rotation reversal in two-dimensional Glass/ZnO(500Å)/Fe40Pd40B20(YÅ). Y. Chen and H. Jheng 1. magnetoplasmonic crystals. J. Gao1, S. Zhang1, W. Xia1, Department of Materials Science and Engineering, I-Shou L. Chen1, S. Tang1 and Y. Du11. Nanjing National Laboratory of University, Kaohsiung Taiwan 840, R.O.C., Kaohsiung, Taiwan Microstructures, Department of Physics and Jiangsu Provincial Laboratory for Nanotechnology, Nanjing University, Nanjing, AT-11. Unexpected magnetic anisotropy induced by oxygen vacancy Jiangsu, China 1 1 in anatase TiO2: A first-principles study.B. Shao , Y. Zhang , Y. Lu 1, M. Feng2 and X. Zuo11. College of Information Technical AT-04. Evaluation of the reversible component in the hysteretic Science, Nankai University, Tianjin, China; 2. School of Physics, processes observed in nanoparticulate spin crossover Nankai University, Tianjin, China compounds.A. Atitoaie1, R. Tanasa1, C. Enachescu1 and 1 A. Stancu 1. Department of Physics, Alexandru Ioan Cuza AT-12. Ab initio calculations on magnetism induced by composite University of Iasi, Iasi, Romania defects in magnesium oxide.Y. Zhang1, B. Shao1, Y. Lu1, M. Feng2 and X. Zuo11. College of Information Technical AT-05. Tuning Faraday angle of Ce:YIG film with the deposition and Science, Nankai University, Tianjin, China; 2. School of Physics, annealing atmosphere. Q. Yang1, Q. Wen1, H. Zhang1 and Nankai University, Tianjin, China L. Jin11. University of Electronic Science and Technology of China, Chengdu, China AT-13. Structural and Magnetic Properties of Mn3-xPtxSn (x = 0, 0.5, 1) Nanomaterials. A.D. Nelson1,2, Y. Huh1,2, P. Kharel2,3, V.R. Shah2, R. Skomski2,3 and D.J. Sellmyer2,31. Physics, South AT-06. Optical and magneto-optical spectroscopy of Co(2-x)Fe(1+x)Si thin films. M. Veis1, L. Beran1, R. Antos1, J. Hamrle2, D. Legut2, Dakota State University, Brookings, SD; 2. Nebraska Center for K. Postava2, J. Pistora2, T. Kuschel3 and G. Reiss31. Institute of Materials and Nanoscience, University of Nebraska, Lincoln, NE; Physics, Charles University in Prague, Prague, Czech Republic; 3. Physics and Astronomy, University of Nebraska, Lincoln, NE 2. Nanotechnology Centre, VSB-Technical University of Ostrava, Ostrava, Czech Republic; 3. Faculty of Physics, Bielefeld AT-14. A site-selective antiferromagnetic ground state in layered University, Bielefeld, Germany pnictide-oxide BaTi2As2O. L. Zou1, X. Yu1, D. Liu1 and H. Lin21. Research Laboratory of Computational Materials Sciences, Institute of Solid State Physics, the Chinese Academy of Sciences, Hefei, Anhui, China; 2. Beijing Computational Science Research Center, Beijing, China 46 PROGRAM PROGRAM 47

AT-15. High current sensitivity and large magnetoelectric effect in AU-06. Faster motion of double 360o domain walls system induced by ring-type magnetoelectric composite based on concentric spin-polarized current.S. Zhang1, Q. Zhu1, C. Mu1, Q. Zheng1, magnetostrictive composite ring and piezoelectric ceramic X. Liu1, Q. Liu1 and J. Wang11. Key Laboratory for Magnetism 1 1 1 ring. C. Leung , S. Or and S. Ho 1. Electrical Engineering, The and Magnetic Materials of Ministry of Education, Lanzhou, China Hong Kong Polytechnic University, Kowloon, Hong Kong

AU-07. Controlling the transverse domain wall mobility and polarity AT-16. The absorption property of garnet film prepared by liquid in magnetic nanowires: a parameter study. J. Vandermeulen1,2, 1 1 phase epitaxy method in terahertz band. Q. Yang , H. Zhang , B. Van de Wiele1, A. Vansteenkiste2, B. Van Waeyenberge2 and 1 1 Q. Wen and L. Jin 1. University of Electronic Science and L. Dupré11. Department of Electrical Energy, Systems and Technology of China, Chengdu, China Automation, Ghent University, Ghent, Belgium; 2. Department of Solid State Physics, Ghent University, Ghent, Belgium

AU-08. Current and field induced domain wall motion in ultra-thin 1 TUESDAY EXHIBIT HALL magnetic layer with strong spin-orbit interaction. E. Jué , I.M. Miron1, O. Boulle1, S. Pizzini2, J. Vogel2, A. Thiaville3, MORNING S. Rohart3, L. Buda-Prejbeanu1, A. Lopez1, S. Auffret1, 9:30 M. Bonfim4, A. Schuhl2 and G. Gaudin11. SPINTEC, Grenoble, France; 2. Institut Néel, Grenoble, France; 3. Lab. Physique des Session AU solides, Université Paris-Sud, Orsay, France; 4. Departamento de INTERACTING DOMAIN WALLS Engenharia Elétrica, Universidade Federal do Paraná, Curitiba, Brazil (Poster Session) Olivier Fruchart, Co-Chair AU-09. Understanding and Controlling Stochastic Domain Wall Gong Chen, Co-Chair Depinning. T.J. Hayward11. Department of Engineering Materials, Univ Sheffield, Sheffield, South Yorkshire, United AU-01. Current-induced domain-wall deformation caused by Oersted Kingdom field in ferromagnetic nanowires with Perpendicular Magnetic 1 1 1 Anisotropy. S. Yoo , K. Moon and S. Choe 1. Physics, Seoul AU-10. Stochasticity of domain wall depinning in NiFe and FePt National University, Seoul, Republic of Korea nanowires under fields and currents.V. Nguyen1, W. Savero Torres2,4, P. Laczkowski3, L. Vila2,4, A. Marty2,4, L. Notin2,4, 2,4 2,4 2,4 2,4 AU-02. Motion of magnetic domain walls driven by low current C. Beigne , C. Vergnaud , M. Jamet and J. Attane 1. Micro density in perpendicularly magnetized CoFe/Pd multilayer et Nanomagnetisme, Institute Neel, Grenoble, Rhone Alpes, nanowire. Z. Meng1,2, D. Ngo1, M. Kumar1, J. Qiu2, G. Han2 and France; 2. INAC/SP2M, CEA, Grenoble, Rhone Alpes, France; 3. K. Teo11. Electrical and Computer Engineering, National Unite Mixte de physique, CNRS/Thales, Paris, Ile de France, University of Singapore, Singapore, Singapore; 2. Data Storage France; 4. Universite Joseph Fourier, Grenoble, Rhone Alpes, Institute, Agency for Science, Technology and Research France (A*STAR), Singapore, Singapore AU-11. 360 Domain Wall nucleation in thin films. A.L. Gonzalez 1 2 3 1 AU-03. Dependence of the domain wall propagation on the notch Oyarce , T. Trypniotis , Y. Nakatani and C. Barnes 1. geommetry in Permalloy nanowires. J. Brandão1, P. Soledade1, Department of Physics, Cambridge, Cambridge, Cambridgeshire, R. Novak1, A. Silva1 and . Sampaio11. Centro Brasileiro de United Kingdom; 2. Department of Physics, University of Cyprus, Pesquisas Físicas, Rio de Janeiro, Brazil Cyprus, Cyprus; 3. Graduate School of Informatics and Engineering, University of Electro-communications, Chofu, Japan

AU-04. Simulation of Oscillatory Domain Wall Motion Driven by AU-12. Current-Induced Domain Wall Motion in Tb/Co-Based Spin Waves in Perpendicular Magnetic Anisotropy Nanostrip. 1 1 1 Multilayer Wires: Effect of Layered Structure. B. Do and L. Chang and S. Lee 1. Institute of Physics, Academia Sinica, 1 Taipei, Taiwan H. Awano 1. Toyota Technological Institute, Nagoya, Japan

AU-05. Opposite Dzyaloshinskii-Moriya Interactions in Pt/Co/Pt and Pd/Co/Pd Films. D. Kim1, S. Je1, S. Yoo1,2, B. Min2, K. Lee3,4 and S. Choe11. Center for Subwavelength Optics and Department of Physics, Seoul National University, Seoul, Republic of Korea; 2. Center for Spintronics Research, Korea Institute of Science and Technology, Seoul, Republic of Korea; 3. Department of Materials Science and Engineering, Korea University, Seoul, Republic of Korea; 4. KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul, Republic of Korea 48 PROGRAM PROGRAM 49

AU-13. Highly asymmetric magnetic domain wall propagation due to AV-03. First-principles survey on the doping of Ga in Nd2Fe14B. coupling to a periodic pinning potential. R.L. Novak1,2, X. Liu1, Q. Zhang1 and P. Liu11. Physics, University of Texas at P.J. Metaxas3,4, J. Jamet2, R. Weil2, J. Ferré2, A. Mougin2, Arlington, Arlington, TX S. Rohart2, R.L. Stamps5, P. Zermatten6, G. Gaudin6, V. Baltz6 and B. Rodmacq61. Centro Brasileiro de Pesquisas Fisicas, Rio de AV-04. Effects of the deformation on the crystal field parameter of Janeiro, RJ, Brazil; 2. Laboratoire de Physique des Solides, Nd ions in Nd Fe B. T. Suzuki1, Y. Toga1 and A. Sakuma11. Université Paris-Sud, CNRS, UMR 8502, Orsay, France; 3. 2 14 Department of Applied Physics, Tohoku University, Sendai, Japan School of Physics, University of Western Australia, Crawley, WA, Australia; 4. Unité Mixte de Physique CNRS/Thales, UMR 137, Palaiseau, France; 5. SUPA-School of Physics and Astronomy, AV-05. Effect of Dy/Nd double layer on coercivity in Nd-Fe-B thin University of Glasgow, Glasgow, United Kingdom; 6. SPINTEC, films. K. Koike1, J. Umezawa1, H. Ishikawa1, D. Ogawa1, URA CNRS/CEA 2512, CEA-Grenoble, Grenoble, France T. Miyazaki2, H. Kato1 and Y. Ando21. Applied Mathematics and Physics, Yamagata University, Yonezawa, Yamagata, Japan; 2. Applied Physics, Tohoku University, Sendai, Miyagi, Japan AU-14. Current-induced motion of vortex domain walls in permalloy/Pt bilayers.V. Nguyen1, Z. Ishaque1, S. Pizzini1, N. Rougemaille1, M. Bonfim2, O. Fruchart1, J. Toussaint1, AV-06. Mechanism of Nd-Cu liquid phase diffusion in hot pressed T. Mentes3, A. Locatelli3 and J. Vogel11. Nanosciences, CNRS, and hot deformation nanocomposite magnets.X. Tang1, Institut Néel, Grenoble, France; 2. Departamento de Engenharia R. Chen1, W. Yin1, X. Tang1, D. Lee2 and A. Yan11. Key Elétrica, Universidade do Paraná, Curitiba, Brazil; 3. ELETTRA, Laboratory of Magnetic Materials and Devices, Zhejiang Sincrotone Trieste, Trieste, Italy Province Key Laboratory of Magnetic Materials and Application Technology, Ningbo Institute of Materials Technology & Engineering, Chinese Academy of Sciences, Ningbo, China; 2. AU-15. Asymmetric domain wall depinning from symmetric notches University of Dayton, Dayton, OH in nanowires. A. Kunz1, D.T. Kutzke1, H.H. Le1 and J. Vogeler- Wunsch11. Physics, Marquette University, Milwaukee, WI AV-07. Magnetic properties of consolidated cobalt carbide nanoparticles produced by modified polyol process. AU-16. A novel multi-level single-bit data storage device. J.E. Bickel1 S. Bennett1,2, M. Zamanpour2,3, Y. Chen1,2 and V.G. Harris1,31. and K.E. Aidala11. Department of Physics, Mount Holyoke Department of Electrical and Computer Engineering, College, South Hadley, MA Northeastern University, Boston, MA; 2. Center for Microwave Magnetic Materials and Integrated Circuits, Northeastern, Boston, MA; 3. Department of Chemical Engineering, Northeastern University, Boston, MA TUESDAY EXHIBIT HALL MORNING AV-08. Large enhancement in magnetic properties and grain texture in polycrystalline hexaferrites compacts using gluconic acid as 9:30 an ordering medium. O. Obi1, Y. Chen1, L. Burns2, H. Chang1 and V.G. Harris11. Center for Microwave Magnetic Materials and Session AV Integrated Circuits, Electrical and Computer Engineering Dept., BORIDE PERMANENT MAGNETS: Northeastern University, Boston, MA; 2. Metamagnetics Inc., FUNDAMENTALS AND ADVANCED Canton, MA CHARACTERIZATION I AV-09. Electrochemical corrosion behavior, microstructure and (Poster Session) magnetic properties of sintered Nd-Fe-B permanent magnet Gino Hrkac, Chair doped by CuZn5 powders. W. Liu1, Z. Wang1, C. Sun1, M. Yue1, Y. Liu1, D. Zhang1 and J. Zhang11. College of Materials Scicence and Engineering, Beijing University of Technology, Beijing, AV-01. Growth of highly oriented Nd-Fe-B films and its China magnetization reversal behaviors. R. Goto1, K. Kadonosawa1, S. Okamoto1, N. Kikuchi1 and O. Kitakami11. IMRAM, Tohoku Univ., Sendai, Japan AV-10. Texture formation of hot-deformed nanocomposite Nd2Fe14B/α-Fe magnets by Nb and Zn additions. Y. Ma 1,21. College of Metallurgical and Materials Engineering, Chongqing AV-02. Analysis of Demagnetization Process of Nd–Fe–B Sintered University of Science and Technology, Chongqing, Chongqing, Magnets at Elevated Temperatures by Magnetic Domain 1 China; 2. Department of Physics, University of Texas at Observation Using Kerr Microscope. M. Takezawa , Arlington, Arlington, TX H. Ogimoto1, Y. Kimura1 and Y. Morimoto11. Department of Applied Science for Integrated System Engineering, Faculty of Engineering, Kyushu Institute of Technology, Kitakyushu, Japan AV-11. Superferrimagnetism in Hard Nd-Fe-B Thick Films, an Original Concept for Coercivity. O. Akdogan1, N.M. Dempsey1 and D. Givord11. Institut Néel, CNRS-UJF, Grenoble, France 50 PROGRAM PROGRAM 51

AV-12. Dipolar energy of Nd-Fe-B nanocrystalline magnets in AW-04. Self-positioning and Rolling Microrobots Actuated by magnetization reversal process. H. Ohtori1, K. Iwano1, Magnetic Navigation System on Arbitrary Thin Surfaces. C. Mitsumata2, Y. Takeichi1, M. Yano3, A. Kato3, N. Miyamoto3, S. Jeon1, G. Jang1, J. Nam1 and K. Choi11. Dept. of Mechanical T. Shoji3, A. Manabe3 and K. Ono11. Institute of Materials Engineering, PREM Lab., Hanyang University, Seoul, Republic of Structure Science, High Energy Accelerator Research Korea Organization (KEK), Tsukuba, Japan; 2. National Institute of Materials Science, Tsukuba, Japan; 3. Toyota Motor Corp., AW-05. Nanogap Device for Single Nanometric Custer Transport Toyota, Japan Properties Measurement. R. Morel1, J. Rousseau1, A. Brenac1, L. Vila1, C. Beigné1 and A. Marty11. INAC/SP2M and Université AV-13. Perpendicular magnetic anisotropic Pr–Fe–B thin films on Joseph-Fourier, CEA Grenoble, Grenoble, France glass substrates. C. Huang1, A. Sun1, H. Chang2, F. Yuan3, S. Chang2 and W. Chang41. Department of Chemical Engineering AW-06. Magnetic microrings fabrication in T-junction microfluidics. and Materials Science, Yuan-Ze University, Taoyuan, Taiwan; 2. C. Lee1, T. Lan1 and M. Lai11. Department of Power Mechanical Department of Physics, Tunghai University, Taichung, Taiwan; 3. Engineering, National Tsing Hua University, Hsinchu, Taiwan Advanced Sensor Laboratory, iSentek Ltd., Taipei, Taiwan; 4. Department of Physics, National Chung Cheng University, Chia- Yi, Taiwan AW-07. Dynamic Electromagnetic Characteristic Analysis of Seawater Impacted by the Strong Rotational Magnetic Field of Submersible Motor.J. Chen1, C. Zhen1, J. Xu1, X. Li1, S. Ho2 and AV-14. Magnetic properties of Nd-Ga-Fe -Nb-B alloy. H. Kim1, bal W. Fu 21. College of Mechanical Engineering, Donghua C. Kim1, S. An2, K. Choi2 and M. Choi21. physics, Kookmin University, Shanghai, China; 2. Departments of Electrical university, Seoul, Republic of Korea; 2. Corporate R&D, Engineering, Hong Kong Polytechnic, Hong Kong, China Samsung Electro-Mechanics, Suwon, Republic of Korea

AW-08. Quantitative analysis of Low frequency magnetic shielding AV-15. Effect of Excess Nd on Microstructural and Magnetic effectiveness in an open magnetic circuit. Z. Xu11. University of Properties of NdFeB Thick Films. N. Gunduz Akdogan1, Texas at Dallas, Dallas, TX G. Ciuta1, N.M. Dempsey1 and D. Givord11. Institut Neel, CNRS- UJF, Grenoble, France AW-09. A novel measurement method of power losses in magnetic cores. R. Gozdur11. Department of Semiconductor and Optoelectronic Devices, Lodz University of Technology, Lodz, Poland TUESDAY PLAZA BALLROOM A MORNING AW-10. A self-powered sensor for AC electric current monitoring in 9:30 electric power grid.W. He 1, P. Li 1, Y. Wen1, J. Zhang1, J. Yang1, A. Yang1, C. Lu1 and W. Li11. Research Center of Sensors and Session AW Instruments, Chongqing University, Chongqing, China NEW APPLICATIONS AND MEASUREMENTS AW-11. Pseudo-“Blindsight” under Exposure to ELF Electromagnetic (Poster Session) Fields. H. Nakagawa1, K. Masamune2, M. Kotani1 and S. Ueno31. Mitch Wallis, Chair Department of Electrical and Electronic Engineering, Graduate School of Engineering, Tokyo Denki University, Adachi-ku, Tokyo, AW-01. Surface plasmon induced enhancement with magneto-optical Japan; 2. Department of Mechano-Informatics, Graduate School bilayer. H. Huang1, K. Liao1 and Z. Wei11. Department of Power of Information Science and Technology, The University of Tokyo, Mechanical Engineering National Tsing Hua University, Hsinchu, Bunkyo-ku, Tokyo, Japan; 3. Department of Applied Quantum Taiwan Physics, Graduate School of Engineering, Kyushu University, Higashi-ku, Fukuoka, Japan

AW-02. Writing Magnetic Patterns with Surface Acoustic Waves. W. Li 1, B. Buford1, A. Jander1 and P. Dhagat11. School of AW-12. Detailed Analysis of Permanent Magnets by means of Free 1 1 Electrical Engineering and Computer Science, Oregon State Field Measurements. H. Husstedt and M. Kaltenbacher 1. University, Corvallis, OR Institute for Mechanics and Mechatronics, Vienna University of Technology, Vienna, Austria

AW-03. Inkjet Printing of Magnetic Materials with Aligned Anisotropy. H. Song1, J. Spencer1, A. Jander1, P. Dhagat1, J. Nielsen2, J. Stasiak2 and V. Kasperchik21. School of Electrical Engineering and Computer Science, Oregon State University, Corvallis, OR; 2. Hewlett-Packard Company, Corvallis, OR 52 PROGRAM PROGRAM 53

AW-13. Experimental and numerical study on the manipulation of AX-05. Analysis of Hanle-effect signals observed in Si-channel spin magnetic particles in microfluidic channels. X. Han1,2, accumulation devices. Y. Takamura1,2, A. Sadano1, T. Akushichi1, Q. Cao1,2, X. Zhou1,2 and L. Li1,21. Wuhan National High T. Okishio1, Y. Shuto1 and S. Sugahara1,31. Imaging Science and Magnetic Field Center, Huazhong University of Science and Engineering Laboratory, Tokyo Institute of Technology, Technology, Wuhan, China; 2. State Key Laboratory of Advanced Yokohama, Japan; 2. Department of Physical Electronics, Tokyo Electromagnetic Engineering and Technology, Huazhong Institute of Technology, Tokyo, Japan; 3. CREST, Japan Science University of Science and Technology, Wuhan, China and Technology Agency, Kawaguchi, Japan

AW-14. Barkhausen spectroscopy: Non-destructive characterization AX-06. Inelastic electron tunneling spectroscopy study of of magnetic materials as a function of depth. O. Kypris1, CoFe/MgO/n+-Si junctions. T. Inokuchi1, M. Ishikawa1, C.I. Nlebedim1,2 and D.C. Jiles1,21. Department of Electrical and H. Sugiyama1, T. Tanamoto1 and Y. Saito11. Corporate R&D Computer Engineering, Iowa State University, Ames, IA; 2. Ames Center, Toshiba Corporation, Kawasaki, Japan Laboratory, US Department of Energy, Iowa State University, Ames, IA AX-07. Electronic Transport in Semiconductors Nanowires with Non- Magnetic and Magnetic Contacts. C.F. Cerqueira1, A. Pinto1, AW-15. Complementary study of microstress state of P91 steel using N. Rios2, E.H. Falcão2, A.S. Gomes1, M. Sacilottic3,4 and mechanical Barkhausen and magnetoacoustic emission L.C. Sampaio11. Centro Brasileiro de Pesquisas Físicas, Rio de phenomena and XRD technique. B. Augustyniak1, Janeiro, Brazil; 2. Dep. de Química Fundamental, Universidade L. Piotrowski1, P. Maciakowski1, M. Chmielewski1, Federal de Pernambuco, Recife, Brazil; 3. Dep. de Física, J. Karczewski1, M. Lech-Grega2 and J. Zelechowski21. Applied Universidade Federal de Pernambuco, Recife, Brazil; 4. Physics and Mathematics, Gdansk University of Technology, Nanoform, Université de Bourgogne, Bourgogne, France Gdansk, Poland; 2. The Institute of Non-Ferrous Metals, Skawina, Poland AX-08. On the origin of magnetic ordering in amorphous GaMnN thin films. W.A. Iwamoto1, D.M. Leite2, A.L. Pereira2, J.H. da Silva2, R.R. Urbano1, C. Rettori1,3 and P.G. Pagliuso11. Departamento de Eletrônica Quântica, IFGW/UNICAMP, Campinas, São Paulo, Brazil; 2. Departamento de Física, TUESDAY PLAZA BALLROOM A UNESP, Bauru, São Paulo, Brazil; 3. Centro de Ciências Naturais MORNING e Humanas, Universidade Federal do ABC, Santo André, São 9:30 Paulo, Brazil

Session AX AX-09. The influence of conductivity and Co particle size on the SEMICONDUCTOR MAGNETISM I magnetoresistance of Co-ZnO granular films. X. Li1,2, L. Cheng1, Y. Gao1, Z. Quan1, X. Qin1, H. Blythe2, G. Gehring2 (Poster Session) and X. Xu11. School of Chemistry and Materials Science, Shanxi Michael Flatté, Chair Normal University, Linfen, Shanxi, China; 2. Department of Physics and Astronomy, University of Sheffield, Sheffield, United AX-01. Effect of CoFe insertion on spin injection properties of Kingdom 1 1 1 Co2MnSi/CoFe/n-GaAs junctions. Y. Ebina , T. Akiho , H. Liu , 1 1 M. Yamamoto and T. Uemura 1. Graduate School of Information AX-10. Evidence for room-temperature ferromagnetism of hydrogen- Science and Technology, Hokkaido Univ., Sapporo, Japan mediated ZnCoO using ESR, XAS, and the anomalous Hall effect. S. Lee1, Y. Cho2, B. Kim1, D. Cho3, J. Park1, Y. Choi4, 5 1 AX-02. Magnetic Properties of Epitaxial Fe/MgO/InAs(001) Thin I. Takeuchi and S. Jeong 1. Department of Cogno-Mechatronics Films. J. Jo1, K. Kim2, H. Kim2, J. Chang2 and S. Lim11. Engineering, Pusan National University, Miryang, Republic of Department of Materials Science and Engineering, Korea Korea; 2. Crystal Bank Research Institute, Pusan National University, Seoul, Republic of Korea; 2. Spin Convergence University, Miryang, Republic of Korea; 3. Institute for Basic Research Center, Korea Institute of Science and Technology, Science, Seoul National University, Seoul, Republic of Korea; 4. Seoul, Republic of Korea Korea Atomic Energy Research Institute, Daejeon, Republic of Korea; 5. Materials and Science Engineering, University of Maryland, College Park, MD AX-03. Time-resolved study of dynamic electrical spin transport in Fe/GaAs devices. J. Sizeland1, T. Cheng1, Y. Xu1, V. Lazarov1 and J. Wu11. Physics, University of York, York, North Yorkshire, AX-11. Electron density study on the hydrogen effect in Co-doped 1 1 1 1 1 United Kingdom ZnO. J. Park , S. Lee , B. Kim , W. Kim , Y. Cho , C. Moriyoshi2, Y. Kuroiwa2, C. Park3 and S. Jeong11. Cogno- Mechatronics Engineering, Pusan National University, Miryang, AX-04. Non-equilibrium study of spin wave interference in Rashba Republic of Korea; 2. Physical Science, Hiroshima University, 1 and Dresselhaus (001) spin-orbital couplings. K. Chen and Higashi-Hiroshima, Japan; 3. Physical Education, Pusan 1 C. Chang 1. National Taiwan University, Taipei City, Taiwan National University, Busan, Republic of Korea 54 PROGRAM PROGRAM 55

AX-12. Ferromagnetism at Room Temperature in Cr-Doped Anodic 3:18 Titanium Dioxide Nanotubes. Y. Liao1, H. Zhang1, J. Li1, 1 1 2 2 BA-04. Material Status and Outlook of STT-Based Memory Z. Zhong , F. Bai , S. Zhang and P. Zhong 1. State Key 1,2 Laboratory of Electronic Thin Film and Integrated Devices, Technology. (Invited) H. Ohno 1. Center for Spintronics University of Electronic Science and Technology, Chengdu, Integrated Systems, Tohoku University, Sendai, Miyagi, Japan; 2. China; 2. School of Technical Physics, Xidian University, Xi’an, Laboratory for Nanoelectronics and Spintronics, Research China Institute of Electrical Communication, Tohoku University, Sendai, Miyagi, Japan

AX-13. Withdrawn 3:54

AX-14. Effect of Cr substitution on the magnetic and magneto- BA-05. STT-MRAM technologies for Normally-Off Computing. 1 2 2 1 3 transport properties of Fe Mn Cr Si alloys. L. Pal1, S. Gupta1 (Invited) K. Ando , S. Fujita , J. Ito , S. Yuasa , Y. Suzuki , 2 1-x x 4 5 2 and K.G. Suresh11. Physics, Indian Institute of Technology Y. Nakatani , T. Miyazaki and H. Yoda 1. National Institute of Bombay, Mumbai, India Advanced Industrial Science and Technology (AIST), Tsukuba, Ibaraki, Japan; 2. Toshiba Corporation, Kawasaki, Kanagawa, Japan; 3. Graduate School of Engineering Science, Osaka University, Toyonaka, Osaka, Japan; 4. Department of Communication Engineering and Informatics, University of TUESDAY PLAZA BALLROOM BC Electro-Communication, Chofu, Tokyo, Japan; 5. WPI-AIMR, Tohoku University, Sendai, Miyagi, Japan AFTERNOON 1:30

Session BA SYMPOSIUM ON MATERIALS ADVANCES OF TUESDAY PLAZA BALLROOM F SPIN-TORQUE SWITCHED MEMORY AFTERNOON 1:30 DEVICES FOR SILICON INTERGRATION Jonathan Sun, Chair Session BB CONTROLLING DOMAIN WALLS 1:30 Steven McVitie, Chair BA-01. Properties of CMOS-Integrated Magnetic Tunnel Junction Arrays for Spin-Torque Magnetoresistive Random Access 1:30 Memory. (Invited) J. Slaughter1, S. Aggarwal1, S. Alam1, T. Andre1, H.J. Chia1, M. DeHerrera1, S. Deshpande1, BB-01. Domain wall manipulation using thermal magnons. D. Houssameddine1, J. Janesky1, F.B. Mancoff1, K. Nagel1, P.B. Ndiaye1 and A. Manchon11. Material Science & Engineering, M.L. Schneider1, N.D. Rizzo1 and R. Whig11. Everspin King Abdullah University of Science and Technology, Thuwal, Technologies, Inc., Chandler, AZ Saudi Arabia

2:06 1:42 BA-02. Materials advances in perpendicularly magnetized MgO- BB-02. Domain Wall Assisted Ordering of Coupled Nanomagnets. tunnel junctions for STT-MRAM. (Invited) D. Worledge1, E. Varga1, G. Csaba1, G.H. Bernstein1 and W. Porod11. Electrical S.L. Brown1, W. Chen1, J. Harms1, G. Hu1, R. Kilaru1, W. Kula3, Engineering, University of Notre Dame, Notre Dame, IN G. Lauer1, L.Q. Liu1, J. Nowak1, S. Parkin2, A. Pushp2, 1 1 3 1 S. Murthy , R.P. Robertazzi , G. Sandhu and J.Z. Sun 1. IBM- 1:54 Micron MRAM Alliance, IBM TJ Watson Research Center, Yorktown Heights, NY; 2. IBM-Micron MRAM Alliance, IBM BB-03. Domain wall pinning dependent on nanomagnet state. R. van Almaden Research Center, San Jose, CA; 3. IBM-Micron MRAM Mourik1,2, C. Rettner1, B. Hughes1, B. Koopmans2 and Alliance, Micron, Boise, ID S. Parkin11. IBM Almaden Research Center, San Jose, CA; 2. Eindhoven University of Technology, Eindhoven, Netherlands 2:42 2:06 BA-03. Magnetization dynamics in perpendicular STT-MRAM cells with high spin-torque efficiency and thermal stability. BB-04. Control of domain wall motion by electric field in Ta-CoFeB- (Invited) L. Thomas1, G. Jan1, J. Zhu1, H. Liu1, Y. Lee1, S. Le1, MgO ultra-thin films with perpendicular anisotropy. W. Lin1, R. Tong1, K. Pi1, Y. Wang1, T. Zhong1, T. Torng1 and P. Wang11. N. Vernier1, S. Eimer1, G. Agnus1, K. Garcia1, B. Ockert2 and TDK-Headway Technologies Inc., Milpitas, CA D. Ravelosona1,31. University of Paris Sud, Orsay, France; 2. Singulus, Kahl, Germany; 3. SILTENE, Orsay, France 56 PROGRAM PROGRAM 57

2:18 3:30 BB-05. Voltage control and nanoscale engineering of ferromagnetic BB-11. Distribution of critical current density for magnetic domain domains in single crystal FeGa. R.P. Beardsley1, D.E. Parkes1, wall motion. S. Fukami1, M. Yamanouchi1,2, K. Kim3, S.R. Bowe1, M. Wang1, R.P. Campion1, K.W. Edmonds1, T. Koyama3, D. Chiba3,4, S. Ikeda1,2, N. Kasai1, T. Ono3 and I. Isakov3, P. Warburton3, S.A. Cavil2 and A.W. Rushforth11. H. Ohno1,21. Center for Spintronics Integrated Systems, Tohoku Physics and Astronomy, The University of Nottingham, University, Sendai, Miyagi, Japan; 2. Laboratory for Nottingham, United Kingdom; 2. Diamond Light Source, Didcot, Nanoelectronics and Spintronics, RIEC, Tohoku University, Oxfordshire, United Kingdom; 3. London Centre for Sendai, Miyagi, Japan; 3. Institute for Chemical Research, Kyoto Nanotechnology, London, United Kingdom University, Uji, Kyoto, Japan; 4. PRESTO, Japan Science and Technology Agency, Kawaguchi, Saitama, Japan 2:30 3:42 BB-06. Voltage-gated domain-wall pinning in a Pt/Co/AlOx nanostrip.J.H. Franken1, Y. Yin1, A.J. Schellekens1, A. van den BB-12. Three-dimensional magnetic nanowires grown by focused Brink1, H.J. Swagten1 and B. Koopmans11. Department of electron beam induced deposition. A. Fernandez-Pacheco1, Applied Physics, Eindhoven University of Technology, Eindhoven, L.E. Serrano-Ramon2, J.M. Michalik2, R. Ibarra2,3, J.M. De Netherlands Teresa2,3, L. O’Brien1, D. Petit1, J.H. Lee1 and R.P. Cowburn11. Cavendish Laboratory, University of Cambridge, Cambridge, United Kingdom; 2. Institute of Materials Science of Aragon, 2:42 University of Zaragoza/CSIC, Zaragoza, Spain; 3. Laboratory of BB-07. Switchable spin-current source controlled by magnetic Advanced Microscopy, Institute of Nanoscience of Aragon, domain walls. W. Savero Torres1,2, P. Laczkowski4, V. Nguyen3, University of Zaragoza, Zaragoza, Spain J. Rojas Sanchez5,2, C. Nguyen1,2, L. Vila1,2, A. Marty1,2, 1,2 1,2 1,2 1,2 C. Beigné , L. Notin , M. Jamet and J. Attané 1. 3:54 INAC/S2PM, CEA, Grenoble, Rhone Alpes, France; 2. Université Joseph Fourier, Grenoble, Rhone Alpes, France; 3. Micro et BB-13. Real-space observation and laser control of domain wall Nanomagnetisme, Institute Néel, Grenoble, Rhone Alpes, France; hopping in an ultrathin magnetic wire. J. Tetienne1,2*, 4. Unité Mixte de Physique, CNRS/Thales, Paris, Paris, France; T. Hingant1,2, L. Herrera Diez3, K. Garcia3, J. Kim3, 5. SPINTEC, CEA, Grenoble, rhone alpes, France D. Ravelosona3, S. Rohart4, A. Thiaville4, J. Roch1 and V. Jacques1,21. LAC, Univ. Paris-Sud, ENS Cachan and CNRS, Orsay, France; 2. LPQM, ENS Cachan and CNRS, Cachan, 2:54 France; 3. IEF, Univ. Paris-Sud and CNRS, Orsay, France; 4. BB-08. Detection of Domain Wall motion with a semiconductor LPS, Univ. Paris-Sud and CNRS, Orsay, France device. C. Malec1, B.R. Bennett1 and M. Johnson11. Materials Science and Technology, Naval Research Laboratory, Washington, 4:06 DC BB-14. Controlled Domain Wall Pinning in Nanowires with Perpendicular Magnetic Anisotropy by Localized Fringing 3:06 Fields. S. Breitkreutz1, I. Eichwald1, J. Kiermaier1, G. Hiblot1, BB-09. Spin transfer induced nucleation and dynamics of isolated G. Csaba2, W. Porod2, D. Schmitt-Landsiedel1 and M. Becherer11. magnetic skyrmions in nanostructures.J. Sampaio1, V. Cros1, Lehrstuhl für Technische Elektronik, Technische Universität S. Rohart2, A. Thiaville2 and A. Fert11. Unité Mixte de Physique München, Munich, Germany; 2. Center for Nano Science and CNRS/Thales, Palaiseau, France; 2. Laboratoire de Physique des Technology, University of Notre Dame, Notre Dame, IN Solides, Université Paris-Sud/CNRS, Orsay, France 4:18 3:18 BB-15. Domain Wall Behavior in Patterned Magnetic Films with Low BB-10. Slow Domain Walls for Transporting Ultra-Cold Edge Roughness for Domain Wall Motion based Memory and Atoms.M. Negoita1, M.H. Hodges1, M.T. Bryan1, J.A. Miller1, Logic. J. Currivan1,4, S.A. Siddiqui3, S. Ahn2, G. Beach2, P.W. Fry2, M. Im3, P.J. Fischer3, D.A. Allwood1 and M.A. Baldo3 and C.A. Ross21. Physics, Harvard University, T.J. Hayward11. Department of Engineering Materials, University Cambridge, MA; 2. Materials Science and Engineering, of Sheffield, Sheffield, South Yorkshire, United Kingdom; 2. Massachusetts Institute of Technology, Cambridge, MA; 3. Nanoscience and Technology Centre, University of Sheffield, Electrical Engineering and Computer Science, Massachusetts Sheffield, South Yorkshire, United Kingdom; 3. Centre for X-Ray Institute of Technology, Cambridge, MA; 4. Physics, Optics, Lawrence Berkeley National Lab, Berkeley, CA Massachusetts Institute of Technology, Cambridge, MA 58 PROGRAM PROGRAM 59

TUESDAY PLAZA BALLROOM E 2:42 AFTERNOON BC-07. Mode- and Size- dependent damping in nanomagnets for 1:30 spintronics applications. (Invited) H.T. Nembach1,2, J.M. Shaw2, C.T. Boone2 and T.J. Silva21. JILA, University of Colorado and Session BC NIST, Boulder, CO; 2. Electromagnetics Division, National DAMPING AND SPIN PUMPING Institute of Standards of Technology, Boulder, CO Shigemi Mizukami, Chair 3:18

1:30 BC-08. Dependence of Kambersky Damping on Fermi Level and Spin Orientation. T. Qu1 and R.H. Victora21. School of Physics & BC-01. Size- and temperature-dependent damping in ferromagnetic Astronomy, University of Minnesota, Minneapolis, MN; 2. ultrathin films: role of electron scattering time in Ni81Fe19, Co, Department of Electrical Engineering, University of Minnesota, 1 2 2 2 and CoFeB. C. Cheng , A. Ghosh , S. Auffret , U. Ebels and Minneapolis, MN W.E. Bailey11. Materials Science and Engineering, Applied Physics and Applied Mathematics, Columbia University, New York, NY; 2. SPINTEC, UMR(8191) CEA / CNRS / UJF / 3:30 Grenoble INP ; INAC,, Grenoble, France BC-09. Ferromagnetic Resonance and Spin Pumping in YIG and YIG|Pt Nanodiscs Investigated by MRFM. C. Hahn1, G. de 1 1 1 2 1:42 Loubens , V.V. Naletov , O. Klein , O. d’Allivy Kelly , A. Anane2, R. Bernard2, V. Cros2, J.L. Prieto3 and M. Muñoz41. BC-02. Damping in Nanometer-Thick Yttrium Iron Garnet Films DSM/IRAMIS/SPEC/LNO, CEA Saclay, Gif-sur-Yvette Cedex, 1 1 1 1 Capped by Platinum. Y. Sun , H. Chang , M. Kabatek , Y. Song , France; 2. Unite Mixte de Physique CNRS/Thales, Universite de 1 1 1 1 2 Z. Wang , M. Jantz , W. Schneider , M. Wu , E. Montoya , Paris-Sud, Palaiseau, France; 3. Instituto de Sistemas 2 2 3 3 B. Kardasz , B. Heinrich , S.G. te Velthuis , H. Schultheiss and Optoelectrónicos y Microtecnología (UPM), Madrid, Spain; 4. 3 A. Hoffmann 1. Department of Physics, Colorado State Instituto de Microelectronica de Madrid (CNM, CSIC), Madrid, University, Fort Collins, CO; 2. Physics Department, Simon Spain Fraser University, Burnaby, BC, Canada; 3. Materials Science Division, Argonne National Laboratory, Argonne, IL 3:42

1:54 BC-10. Measurement of intralayer spin diffusion damping using spin wave resonance. Y. Li 1 and W.E. Bailey11. Applied Physics and BC-03. Seed Influence on the Ferromagnetic Resonance Response of Applied Mathematics, Columbia University, New York, NY Co/Ni Multilayers. M.G. Sabino1,2, M. Tran1, C. Sim1, K. Eason1 and Y. Liew2,31. Data Storage Institute, Singapore, Singapore; 2. Department of Electrical and Computer Engineering, National 3:54 University of Singapore, Singapore, Singapore; 3. National BC-11. Asymmetric behavior of the spin pumping in CoFeB/Ta Metrology Center, Singapore, Singapore interface. M. Jamali1, A. Klemm1 and J. Wang11. Electrical & Computer Eng., University of Minnesota, Minneapolis, MN 2:06 BC-04. FMR Study of Eight-Fold Artificial Quasicrystal Arrays. 4:06 V.. Bhat1, B. Farmer1, J. Woods1, T. Hastings1, L. De Long1, 2 2 BC-12. Effect of graphene on cobalt magnetization dynamics. J. Sklenar and J. Ketterson 1. Physics and Astronomy, University A.J. Berger1, W. Amamou2, S. White1, R. Adur1, Y. Pu1, of Kentucky, Lexington, KY; 2. Physics and Astronomy, R. Kawakami2 and P. Hammel11. Physics, The Ohio State Northwestern University, Evanston, IL University, Columbus, OH; 2. Physics and Astronomy, University of California Riverside, Riverside, CA 2:18 BC-05. Precise determination of the spectroscopic g−factor using 4:18 broadband ferromagnetic resonance spectroscopy. J.M. Shaw1, 1 1 1 BC-13. Probing the Spin Pumping Mechanism: Exchange Coupling H.T. Nembach , T.J. Silva and C.T. Boone 1. NIST, Boulder, CO with Exponential Decay in Y3Fe5O12/barrier/Pt Heterostructures. C. Du1, H. Wang1, Y. Pu1, T.L. Meyer2, 2 1 1 2:30 P.M. Woodward , F. Yang and C.P. Hammel 1. Physics, The Ohio State University, Columbus, OH; 2. Chemistry, The Ohio State BC-06. Spin-orbit interaction enhancement in Pt doped Permalloy. University, Columbus, OH A. Hrabec1, F. Gonçalves2, M. Benitez Romero2, G. Burnell1, S. McVitie2, D. McGrouther2, R. Stamps2 and C. Marrows11. School of Physics and Astronomy, University of Leeds, Leeds, United Kingdom; 2. School of Physics and Astronomy, University of Glasgow, Glasgow, United Kingdom 60 PROGRAM PROGRAM 61

TUESDAY PLAZA BALLROOM D 2:30 AFTERNOON BD-06. Strain-tailored magnetic properties of epitaxially grown 1 2 1:30 ultrathin Eu0.7Sr0.3MnO3 films. E. Moon , D. Keavney and S. May11. Department of Materials Science & Engineering, Session BD Drexel University, Philadelphia, PA; 2. Advanced Photon Source, FUNDAMENTAL PROPERTIES AND Argonne National Laboratory, Argonne, IL COOPERATIVE PHENOMENA I: CORRELATED 2:42 SYSTEMS AND SUPERCONDUCTIVITY Andy Christianson, Chair BD-07. Magnetic anisotropy of Fe3O4 films characterized by ferromagnetic resonance. M. Song1,2, J. Lin1, J.G. Lin1, M. Samant3 and S. Parkin31. Center for Condensed Matter 1:30 Sciences, National Taiwan University, Taipei, Taiwan; 2. Physics, National Taiwan University, Taipei, Taiwan; 3. IBM Research BD-01. Electronic structure, magnetic properties, and Division, Almaden Research Center, San Jose, CA magnetostructural transformations of strongly correlated rare earth dialuminides. D. Paudyal1, V.K. Pecharsky1,2 and K.A. Gschneidner, Jr.1,21. The Ames Laboratory, U S department 2:54 of Energy, Iowa State University, Ames, IA; 2. Department of BD-08. An Emergent Spin-Filter at the Interface between Materials Science and Engineering, Iowa State University, Ames, Ferromagnetic and Insulating Layered Oxides. Y. Liu1, IA F.A. Cuellar3, Z. Sefrioui3, J.W. Freeland2, M.R. Fitzsimmons4, C. Leon3, J. Santamaria3 and S. te Velthuis11. Materials Science 1:42 Division, Argonne National Laboratory, Argonne, IL; 2. GFMC, Departamento de Fisica Aplicada III, Universidad Complutense BD-02. Percolation theory and quantum critical systems: a new de Madrid, Madrid, Spain; 3. Advanced Photon Source, Argonne description of the critical behavior in National Laboratory, Argonne, IL; 4. Los Alamos National Ce(Ru Fe ) Ge .J. Gaddy1, T. Heitmann2 and 0.24 0.76 2 2 Laboratory, Los Alamos, NM W. Montfrooij1,21. Department of Physics and Astronomy, University of Missouri, Columbia, MO; 2. Missouri Research Reactor, University of Missouri, Columbia, MO 3:06 BD-09. Evidence of Odd Frequency Triplet Pairing in 1:54 Superconducting Spin-Valves with Cross-Polarized Ferromagnetic Layers. X. Wang1,2, N. Banerjee2, A. Wells2, BD-03. Variance of the strong magnetic interaction of a dysprosium F. Bergeret3,4, M. Blamire2, A. Ruotolo1 and J. Robinson21. boron cluster compound. T. Mori1,2, T. Shishido3, K. Yubuta3, Department of Physics and Materials Science, City University of I. Antonyshyn4 and Y. Grin41. National Institute for Materials Hong Kong, Hong Kong, Hong Kong; 2. Department of Materials Science (NIMS), Tsukuba, Japan; 2. University of Tsukuba, Science and Metallurgy, University of Cambridge, Cambridge, Tsukuba, Japan; 3. Tohoku University, Sendai, Japan; 4. Max United Kingdom; 3. Centro de Física de Materiales, Centro Mixto Planck Institute for Chemical Physics of Solids, Dresden, CSIC-UPV/EHU, San Sebastián, Spain; 4. Donostia International Germany Physics Center, San Sebastián, Spain

2:06 3:18 BD-04. Giant Verwey transition in magnetite thin films. L. Alff1 and BD-10. Angular Dependence of the Superconducting Transition M. Baghaie Yazdi11. Material Science, TU Darmstadt, Temperature in Nb/Co/Cu/Co/CoO Spin Valves. A.A. Jara1, Darmstadt, Germany C. Safranski1 and I.N. Krivorotov11. Physics and Astronomy, University of California, Irvine, Irvine, CA 2:18 BD-05. Spatially Homogeneous Ferromagnetism below the Enhanced 3:30 Curie Temperature in EuO1-x Thin Films. P.M. Monteiro1, BD-11. Supercurrent modulation in Josephson junction barriers A. Ionescu1, .J. Baker2, M. Barbagallo1, S. Langridge2, . Barnes1, based on pseudo-spin valve and magnetic clusters. B. Baek1, . Salman3, A. Suter3, . Prokscha3 and N. Hine11. Cavendish W.H. Rippard1, S.P. Benz1, S.E. Russek1, P.D. Dresselhaus1, Laboratory, University of Cambridge, Cambridge, United M.R. Pufall1 and H. Rogalla11. National Institute of Standards Kingdom; 2. ISIS Facility, STFC Rutherford Appleton Laboratory, and Technology, Boulder, CO Oxon, United Kingdom; 3. Laboratory for Muon-Spin Spectroscopy, Paul Scherrer Institut, Villigen, Switzerland 3:42 BD-12. Structure of spin fluctuations near magnetic instability in iron pnictides. V. Antropov11. ames lab, Ames, IA 62 PROGRAM PROGRAM 63

3:54 2:06 BD-13. Ultrafast transient generation of spin density wave order in BE-04. Controlling Interface Magnetism and Transport via Oxygen the normal state of BaFe2As2. (Invited) K. Kim1,2, A. Pashkin2, Vacancy Ordering in Perovskite Cobaltites. (Invited) S. Bose1, H. Schäfer2, M. Beyer2, M. Porer2,4, T. Wolf5, C. Bernhard3, M. Sharma1, M. Torija1, J. Gazquez2,3, M. Varela2,3, V. Lauter4, J. Demsar2, R. Huber2,4 and A. Leitenstorfer21. Department of H. Ambaye4, R. Goyette4, M. Fitzsimmons5, J. Schmitt1, C. He1, Physics, Chungbuk National University, Cheongju, Republic of J. Borchers6, M. Laver6, S. El-Khatib7,6 and C. Leighton11. Korea; 2. University of Konstanz, Konstanz, Germany; 3. University of Minnesota, Minneapolis, MN; 2. Oak Ridge University of Fribourg, Fribourg, Switzerland; 4. University of National Lab, Oak Ridge, TN; 3. Universidad Complutense de Regensburg, Regensburg, Germany; 5. Karlsruhe Institute of Madrid, Madrid, Spain; 4. Spallation Neutron Source, Oak Ridge Technology, Karlsruhe, Germany National Lab, Oak Ridge, TN; 5. Los Alamos National Lab, Los Alamos, NM; 6. National Institute of Standards and Technology, Gaithersburg, MD; 7. American University of Sharjah, Sharjah, United Arab Emirates

TUESDAY GOVERNOR’S SQ 14 2:42 AFTERNOON 1:30 BE-05. Phase control of half-doped manganite thin films and electroresistance in hybrid ferroelectric/manganite tunnel junctions.D. Gutiérrez1, G. Radaelli2, N. Dix1, F. Sánchez1, Session BE R. Bertacco2 and J. Fontcuberta11. Institut de Ciència de COMPLEX OXIDES: FILMS AND Materials de Barcelona (ICMAB-CSIC), Campus UAB, HETEROSTRUCTURES Bellaterra, Spain; 2. LNESS - Dipartimento di Fisica - Politecnico di Milano, Como, Italy Yaohua Liu, Chair

2:54 1:30 BE-06. Effects of Nb doping level on the electronic transport, 2,3 BE-01. Ferrimagnetism in PrCoO3 epitaxial films. V.V. Mehta , photoelectric effect and magnetoresistance across 4 1 5 4 S. Bose , J.M. Iwata-Harms , E. Arenholz , C. Leighton and La Ca MnO /Nb:SrTiO junctions.J. Wang1, Y. Jiang1, 1,6 0.5 0.5 3 3 Y. Suzuki 1. Department of Materials Science and Engineering, Z. Wu1 and J. Gao11. Department of Physics, The University of University of California, Berkeley, Berkeley, CA; 2. Materials Hong Kong, Hong Kong, Hong Kong Sciences Division, Lawrence Berkeley National Laboratory, Berkeley, CA; 3. San Jose Research Center, HGST, A Western Digital Company, San Jose, CA; 4. Department of Chemical 3:06 Engineering and Materials Science, University of Minnesota, BE-07. Large enhancement of Hall resistivity near magnetically Minneapolis, MN; 5. Advanced Light Source, Lawrence Berkeley driven percolation transition in anisotropically-strained National Laboratory, Berkeley, CA; 6. Department of Applied 1 1 1 1 La0.67Ca0.33MnO3 L. Yu , X. Zhang , S. von Molnár , P. Xiong , Physics and Geballe Lab for Advanced Materials, Stanford L. Wang2 and W. Wu21. Department of Physics, Florida State University, Stanford, CA University, Tallahassee, FL; 2. Hefei National Laboratory for Physical Sciences at Microscale, University of Science and 1:42 Technology of China, Heifei, China

BE-02. Magnetic non-uniformity in (La0.4Pr0.6)0.67Ca0.33MnO3 films and measurement of the strain-magnetization coupling 3:18 coefficient. M. Fitzsimmons1, S. Singh1,2, T. Lookman1, H. Jeen3,4, 5 3 4 BE-08. Depth dependent interfacial charge and spin complexity in M.A. Roldan , M. Varela and A. Biswas 1. LANL, Los Alamos, 1 1 La2/3Sr1/3MnO3-BiFeO3 heterostructure. S. Roy , S. Mishra , NM; 2. Solid State Physics Divsion, Bhabha Atomic Research M. Dipanjan2, K. Tarafdar3, L. Wang3, S. Kevan1,5, C. Sanchez- Center, Mumbai, India; 3. ORNL, Oak Ridge, TN; 4. Physics, Hanke4 and A. Gupta21. Advanced Light Source, Lawrence University of Florida, Gainesville, FL; 5. GFMC. Dpto. Fisica Berkeley National Laboratory, Berkeley, CA; 2. MINT Center, Aplicada III, Universidad Complutense de Madrid, Madrid, Spain University of Alabama, Tuscaloosa, AL; 3. Materials Science Division, Lawrence Berkeley National Laboratory, Berkeley, CA; 1:54 4. NSLS, Brookhaven National Laboratory, Upton, NY; 5. Dept. of Physics, University of Oregon, Eugene, OR BE-03. Withdrawn 64 PROGRAM PROGRAM 65

3:30 TUESDAY GOVERNOR’S SQ 15 BE-09. Enhanced magnetism and ferroelectricity in high-quality AFTERNOON

epitaxial PbZr0.52Ti0.48O3/CoFe2O4/La0.7Sr0.3MnO3 multiferroic 1:30 heterostructures grown using the dual-laser ablation technique. D. Mukherjee1, M. Hordagoda1, M. Phan1, Session BF 1 1 1 H. Srikanth , S. Witanachchi and P. Mukherjee 1. Department of RARE EARTH PERMANENT MAGNETS I Physics and Center for Integrated Functional Materials (CIFM), University of South Florida, Tampa, FL Julia Lyubina, Co-Chair Christina Chen, Co-Chair 3:42 1:30 BE-10. Electron Mobility and Magnetotransport in Magnetically 1,3 2,4 4 Doped LaAlO3/SrTiO3 T. Sanders , M. Gray , F. Wong and BF-01. Micromagnetics of shape anisotropy based permanent Y. Suzuki1,41. Applied Physics, Stanford University, Stanford, CA; magnets. S. Bance1, J. Fischbacher1, T. Schrefl1, I. Zins2, 2. Materials Science & Engineering, Stanford University, G. Rieger2 and C. Cassignol21. Industrial Simulation, St Poelten Stanford, CA; 3. Applied Science & Technology Group, UC University of Applied Sciences, St Poelten, Austria; 2. Corporate Berkeley, Berkeley, CA; 4. Materials Science & Engineering, UC Technology, Siemens AG, München, Germany Berkeley, Berkeley, CA 1:42 3:54 BF-02. First principles calculation of substitutional effects of

BE-11. Mapping Spatial Variations in Iron Oxide Phases in Magnetite magnetocrystalline anisotropy in NdFe11Ti and NdFe11TiN. Thin Films Using Infrared Reflectance Microspectroscopy. Y. Harashima1,2, T. Miyake2, H. Kino3,1, S. Ishibashi2 and C.S. Kelley1, S.M. Thompson1, D. Gilks1, S. Poon1, K. Terakura21. ESICMM, National Institute for Materials Science, V.K. Lazarov1, S. LeFrançois2, P. Dumas2 and J.A. Matthew11. Tsukuba, Ibaraki, Japan; 2. Nanosystem Research Institute, Department of Physics, University of York, York, United Kingdom; National Institute of Advanced Industrial Science and Technology, 2. SMIS Beamline, SOLEIL Synchrotron, Paris, France Tsukuba, Ibaraki, Japan; 3. MANA, National Institute for Materials Science, Tsukuba, Ibaraki, Japan 4:06 1:54 BE-12. Emergent Ferromagnetism in CaMnO3 Thin Films and Superlattices. C. Flint1,2, A.J. Grutter4,2, H. Yang6, B.J. Kirby7, BF-03. Micromagnetic Calculations for Hard Magnets. A. Tuggle1, M.R. Fitzsimmons8, J.A. Aguilar9, N.D. Browning10, J.B. Mohammadi1, T. Mewes1 and C. Mewes11. MINT Center / C.A. Jenkins11, E. Arenholz11, V.V. Mehta1,5, U.S. Alaan1,2 and Dept. of Physics and Astronomy, University of Alabama, Y. Suzuki3,21. Department of Materials Science and Engineering, Tuscaloosa, AL Stanford University, Stanford, CA; 2. Geballe Laboratory for Advanced Materials, Stanford University, Stanford, CA; 3. 2:06 Department of Applied Physics, Stanford University, Stanford, CA; 4. Department of Materials Science and Engineering, BF-04. Optimum Geometry of Hard-Soft Nanocomposites. University of California, Berkeley, CA; 5. Materials Science R. Skomski1, B. Balamurugan1 and D.J. Sellmyer11. Physics & Division, Lawrence Berkeley National Laboratory, Berkeley, CA; Astronomy and NCMN, University of Nebraska, Lincoln, NE 6. Department of Materials Science and Chemical Engineering, University of California - Davis, Davis, CA; 7. NIST Center for 2:18 Neutron Research, National Institute of Standards and Technology, Gaithersburg, MD; 8. Los Alamos Neutron Science BF-05. Negative Remanent Magnetization. E. Della Torre1 and Center, Los Alamos National Laboratory, Los Alamos, NM; 9. L.H. Bennett11. George Washington Unversity, Washington, DC Materials Science and Technology Division, Los Alamos National Laboratory, Los Alamos, NM; 10. Chemical and Materials Sciences Division, Pacific Northwest National Laboratory, Richland, WA; 11. Advanced Light Source, Lawrence Berkeley National Laboratory, Berkeley, CA

4:18 BE-13. The Magnetic Properties of Iron Doped Zirconia: from ab initio simulations to the experimental growth and characterization of thin films.D. Sangalli1, A. Lamperti1, E. Cianci1, A. Debernardi1, P. Lupo2, F. Casoli2, F. Albertini2 and L. Nasi21. CNR-IMM, uos Agrate Brianza, Agrate Brianza, Italy; 2. CNR-IMEM, uos Parma, Parma, Italy 66 PROGRAM PROGRAM 67

2:30 3:30 α BF-06. Magnetization reversal in Nd-Fe-B based nanocomposites as BF-11. Morphology and magnetic properties of SmCo3/ -Fe seen by magnetic neutron scattering. J. Bick1, D. Honecker1, nanocomposite magnets prepared via severe plastic F. Döbrich1, K. Suzuki2, E.P. Gilbert3, J. Kohlbrecher4, deformation. N. Poudyal1, W. Xia2, M. Yue3 and J. Liu11. J. Gavilano4, E.M. Forgan5, H. Frielinghaus6, R. Schweins7, Department of Physics, University of Texas at Arlington, P. Lindner7, C. Kübel8, R. Birringer9 and A. Michels11. Physics Arlington, TX; 2. Ningbo Institute of Materials Technology and and Materials Science Research Unit, Universtity of Luxemburg, Engineering, Chinese Academy of Sciences, Ningbo City, Luxembourg, Luxembourg; 2. Department of Materials Zhejiang, China; 3. College of Materials Science and Engineering, Monash University, Clayton, VIC, Australia; 3. Engineering,Beijing University of Technology, Beijing, China Bragg Institute, Australian Nuclear Science and Technology Organisation, Kirrawee DC, NSW, Australia; 4. PSI, Paul 3:42 Scherrer Institut, Villigen, Switzerland; 5. School of Physics and Astronomy, University of Birmingham, Birmingham, United BF-12. Magnetic properties of severe plastic deformed Nd and Sm Kingdom; 6. JCNS, Jülich Centre for Neutron Science, Garching, rare-earth metals. S.V. Taskaev1, V.V. Khovaylo2, A.N. Vasiliev3, Germany; 7. ILL, Institut Laue-Langevin, Grenoble Cedex 9, O.S. Volkova3, K.P. Skokov4, A.P. Pellenen5, D.S. Bataev1 and France; 8. Institute of Nanotechnology and Karlsruhe Nano M.N. Ulyanov11. Chelyabinsk State University, Chelyabinsk, Micro Facility, Karlsruhe Institute of Technology, Eggenstein- Russian Federation; 2. National University of Science and Leopoldshafen, Germany; 9. Experimentalphysik, Universität des Technology “MISIS”, Moscow, Russian Federation; 3. Moscow Saarlandes, Saarbrücken, Germany State University, Moscow, Russian Federation; 4. TU Darmstadt, Darmstadt, Germany; 5. National Research South Ural State 2:42 University, Chelyabinsk, Russian Federation BF-07. Grain boundary modifications in hot-deformed Nd-Fe-B 3:54 permanent magnets by low melting eutectics. S. Sawatzki1, A. Dirks1, I. Dirba1, L. Schultz2 and O. Gutfleisch1,31. Functional BF-13. Origin of magnetic property enhancement in nanocrystalline Materials, TU Darmstadt, Darmstadt, Germany; 2. IFW Dresden, PrCo5. W. Zhang1, S. Valloppilly1, X. Li1, R. Skomski1, J. Shield1 Dresden, Germany; 3. IWKS Group Materials Recycling and and D. Sellmyer11. Nebraska Center for Materials and Resource Strategy, Fraunhofer ISC, Hanau, Germany Nanoscience, University of Nebraska, Lincoln, NE

2:54 4:06 BF-08. Magnetic texture and coercivity of anisotropic nanocrystalline BF-14. Magnetic Properties of CeFe11-xCoxTi with ThMn12 SmCo6.1Si0.9 magnets. S. An1, T. Zhang1 and C. Jiang11. Structure. C. Zhou1, F. Pinkerton2 and J. Herbst21. MEDA Beihang university, Beijing, China Engineering and Technical Services LLC, Southfield, MI; 2. Chemical and Materials Systems Lab, General Motors R&D, 3:06 Warren, MI

BF-09. Single Crystal Structure Analysis of a single Sm2Fe17N3 particle. N. Inami1, Y. Takeichi1, T. Ueno2, K. Saito1, R. Sagayama1, R. Kumai1 and K. Ono11. Institute of Materials Structure Science, High Energy Accelerator Research TUESDAY GOVERNOR’S SQ 16 Organization (KEK), Tsukuba, Japan; 2. National Institute for AFTERNOON Materials Science, Tsukuba, Japan 1:30

3:18 Session BG BF-10. Effect of Zr, Cr, V, Nb, Mo, and Ta substitutions on magnetic SKYRMIONS AND VORTICES properties and microstructure of melt-spun SmCo5 magnets. Ki-Suk Lee, Chair T. Fukuzaki1, H. Iwane1, K. Abe1, R. Tamura2 and T. Oikawa11. Samsung R&D Institute Japan, Tsurumi, Kanagawa, Japan; 2. Tokyo University of Science, Katsushika, Tokyo, Japan 1:30 BG-01. Pairs of Effective Spin Merons in Ferromagnetic Multilayer Elements. S. Wintz1,2, C. Bunce1, A. Neudert1, M. Körner1,2, T. Strache1, M. Buhl1,2, A. Erbe1, S. Gemming1,3, J. Raabe4, C. Quitmann4 and J. Fassbender1,21. Helmholtz-Zentrum Dresden- Rossendorf, Dresden, Germany; 2. Technische Universität, Dresden, Germany; 3. Technische Universität, Chemnitz, Germany; 4. Paul Scherrer Institut, Villigen, Switzerland 68 PROGRAM PROGRAM 69

1:42 2:42 BG-02. Dynamics of Skyrmionic Spin Structures. C. Moutafis1, BG-07. Detection of nonlinear vortex oscillation under strong RF F. Büttner2,3, A. Bisig2,4, B. Krüger2, M. Foerster2, M.A. Mawass2, magnetic field using anisotropic magnetoresistance effect. M. Schneider3, C.M. Günter3, J. Geilhufe6, C. v. Korff X. Cui1,2, S. Yakata1,4 and T. Kimura1,31. Inamori Frontier Schmising3, J. Mohanty3, B. Pfau3, S. Schaffert3, T. Schulz2, Research Center, Kyushu University, Fukuoka, Japan; 2. C.F. Vaz2,7, M. Weigand5, J.H. Franken8, R. Lavrijsen8, J. Raabe1, Graduate School of Information Science and Electrical H.M. Swagten8, M. Kläui2 and S. Eisebitt3,61. Swiss Light Source, Engineering, Kyushu University, Fukuoka, Japan; 3. Department Paul Scherrer Institut, Villigen, Switzerland; 2. Institute of of Physics, Kyushu University, Fukuoka, Japan; 4. CREST, Japan Physics, Johannes-Gutenberg-Universität Mainz, Mainz, Science and Technology Agency, Tokyo, Japan Germany; 3. Institut für Optik und Atomare Physik, Technische Universität Berlin, Berlin, Germany; 4. Fachbereich Physik, 2:54 Universität Konstanz, Konstanz, Germany; 5. Max Planck Institute for Intelligent Systems, Stuttgart, Germany; 6. BG-08. Micromagnetic analysis of dynamical solitons based on the Helmholtz-Zentrum Berlin für Materialien und Energie GmbH, time domain evolution of the topological density. V. Puliafito1, Berlin, Germany; 7. SwissFEL, Paul Scherrer Institute, Villigen S. Komineas2, L. Torres3, O. Ozatay4, T. Hauet5, B. Azzerboni1 PSI, Switzerland; 8. Department of Applied Physics, Center for and G. Finocchio11. Department of Electronic Engineering, NanoMaterials, Eindhoven University of Technology, Eindhoven, Industrial Chemistry and Engineering, University of Messina, Netherlands Messina, Italy; 2. Department of Applied Mathematics, University of Crete, Heraklion, Greece; 3. Department of Applied Physics, 1:54 University of Salamanca, Salamanca, Spain; 4. Department of Physics, Bogazici University, Istanbul, Turkey; 5. Institut Jean BG-03. Skyrmions dynamics and dynamical transition in chiral Lamour, Université de Lorraine-CNRS UMR, Nancy, France metallic magnets. S. Lin1, C. Reichhardt1, C.D. Batista1 and A. Saxena11. Los Alamos National Laboratory, Los Alamos, NM 3:06

2:06 BG-09. Experimental observation of the dynamic modes of a magnetic antivortex. G.A. Riley1, H. Liu1, A. Haldar1,2, M.A. Asmat-Uceda1 BG-04. Coupled vortex dynamics induced by spin transfer torques in and K.S. Buchanan11. Physics, Colorado State University, Fort MgO based magnetic tunnel junction. R. Lebrun1, N. Locatelli1, Collins, CO; 2. Condensed Matter Physics and Material Sciences, F. Abreu Araujo2, H. Kubota3, K. Yakushiji3, J. Grollier1, S. N. Bose National Centre for Basic Sciences, Salt Lake, Kolkata, S. Yuasa3, V. Cros1 and A. Fert11. Unité Mixte de Physique India CNRS/Thales, Palaiseau, France; 2. Université Catholique de Louvain, Louvain la Neuve, Belgium; 3. Spintronic Research 3:18 Center, AIST, Tsukuba, Japan BG-10. Tunability versus Deviation Sensitivity in a non-linear Vortex 1 2 2 1 2:18 Oscillator.S.Y. Martin , C. Thirion , C. Hoarau , C. Baraduc and B. Diény11. SPINTEC, Grenoble, France; 2. Institut Néel, BG-05. Reversal dynamics of single vortex core driven by azimuthal Grenoble, France spin-wave-mode excitations in soft magnetic disk. M. Yoo1 and S. Kim11. National Creative Research Initiative Center for Spin 3:30 Dynamics and Spin-Wave Devices, and Research Institute of Advanced Materials, Department of Materials Science and BG-11. An origin of stochasticity in the formation process of magnetic Engineering, Seoul Natl. Univ., Seoul, Republic of Korea vortex state in asymmetric shaped permalloy disks. M. Im1, K. Lee2, A. Vogel3, J. Hong4, G. Meier3 and P. Fischer11. CXRO, Lawrence Berkeley National Laboratory, Berkeley, CA; 2. UNIST, 2:30 Ulsan, Republic of Korea; 3. University Hamburg, Hamburg, BG-06. 100 ps unidirectional magnetic vortex core reversal – Germany; 4. DGIST, Daegu, Republic of Korea asymmetry matters. H. Stoll1, M. Noske1, M. Kammerer1, M. Sproll1, G. Dieterle1, M. Weigand1, A. Gangwar1,2, 3:42 G. Woltersdorf2, C.H. Back2 and G. Schuetz11. Max Planck Institute for Intelligent Systems (formerly MPI for Metals BG-12. Exploring focused-ion-beam-introduced artificial pinning sites Research), Stuttgart, Germany; 2. Regensburg University, in thin magnetic disks. F. Fani Sani1,2, J.E. Losby1,2, Z. Diao1,2, Regensburg, Germany J.J. Burgess1,2, W.K. Hiebert1,2 and M.R. Freeman1,21. Department of Physics, University of Alberta, Edmonton, AB, Canada; 2. National Institute for Nanotechnology (NINT), Edmonton, AB, Canada 70 PROGRAM PROGRAM 71

3:54 2:18 BG-13. Jamming behavior of magnetic domains in a spiral BH-03. Magnetic marker based homogenous bioassays utilizing antiferromagnetic system. K. Dumesnil1, S.W. Chen2, H. Guo2, rotating magnetic fields. J. Dieckhoff1, M. Schilling1 and K.A. Seu3, S. Roy3 and S.K. Sinha21. P2M, Institut Jean F. Ludwig11. Institute of Electrical Measurement and Lamomur, Vandoeuvre les Nancy, France; 2. UCSD, San Diego, Fundamental Electrical Engineering, TU Braunschweig, CA; 3. ALS, Berkeley, CA Braunschweig, Germany

4:06 2:30 BG-14. Study of Vortex Core Size Effects on Domain Wall Dynamics BH-04. Magnetic Nanocomposite Valve Membrane for the Control of under Nonlocal Spin-Transfer Torque. D. Claudio-Gonzalez1, an Osmotically Powered Drug Delivery Device. A. Zaher1, R.I. Mata-Chávez1, A. Thiaville2 and J. Miltat21. Department of S. Li2, N. Khashab2 and J. Kosel11. Computer, Electrical and Multidisciplinary Studies, Engineering Division Campus Mathematical Science and Engineering, King Abdullah University Irapuato-Salamanca, University of Guanajuato, Yuriria, of Science and Technology (KAUST), Thuwal, Saudi Arabia; 2. Guanajuato, Mexico; 2. Laboratoire de Physique des Solides, Physical Sciences and Engineering, King Abdullah University of University Paris-Sud, CNRS UMR 8502, Orsay, France Science and Technology (KAUST), Thuwal, Saudi Arabia

4:18 2:42 BG-15. The creation of 360° domain walls in ferromagnetic nanorings BH-05. Magnetically controlled droplets of thermosensitive microgel by circular applied magnetic fields. J.E. Bickel1, S.A. Smith1 as advanced agent carriers. O. Yassine1, A. Zaher1, E. Li1, and K.E. Aidala11. Department of Physics, Mount Holyoke A. Alfadhel1, S. Thoroddsen1 and J. Kosel11. King Abdullah College, South Hadley, MA University of Science and Technology, Thuwal, Saudi Arabia

2:54 BH-06. Programmable manipulation of superparamagnetic TUESDAY GOVERNOR’S SQ 12 microbeads at junctions using magnetic domain walls. AFTERNOON E.A. Rapoport1*, D.C. Bono1 and G.S. Beach11. Materials 1:30 Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA Session BH BIO APPLICATIONS: NANOPARTICLES AND 3:06 MICROFLUIDICS BH-07. Barcoding cells using nanowires: Multiplexing and therapeutic potential. A. Sharma1, Y. Zhu2, G. Orlowski3, Thomas Crawford, Chair S. Kansakar4, M. Baylor4, A. Hubel2 and B. Stadler11. Electrical and Computer Engineering, University of Minnesota, Twin Cities, 1:30 Minneapolis, MN; 2. Mechanical Engineering, University of Minnesota, Twin Cities, Minneapolis, MN; 3. Medical School, BH-01. Magnetic approaches to study collective cell mechanics in UMass Medical School, Worcester, MA; 4. Department of Physics 1 2 realistic 3D environments. (Invited) R. Zhao , T. Boudou , and Astronomy, Carleton College, Minneapolis, MN W. Wang1, C. Chen2 and D. Reich11. Physics and Astronomy, Johns Hopkins University, Baltimore, MD; 2. Bioengineering, University of Pennsylvania, Philadelphia, PA 3:18 BH-08. On-chip detection of cell-free DNA with a spintronics lab-on- 2:06 chip system. T. Dias1,2, F.A. Cardoso1, S.A. Martins1,2, J.F. Gaspar3, S. Cardoso1, G. Monteiro2 and P.P. Freitas11. INESC- BH-02. Magnetic micro/nano-tweezers functionalized for biological MN – Microsystems and Nanotechnologies, Lisbon, Portugal; 2. 1,3 1,2 1 and medical applications. C. Iss , H. Joisten , T. Dietsch , Institute for Biotechnology and Bioengineering, Centre for 1 1 1 1 1 S. Leulmi , M. Morcrette , S. Auffret , E. Gautier , P. Sabon , Biological and Chemical Engineering, Lisbon, Portugal; 3. 3 3 3 3 Y. Hou-Broutin , T. Livache , J. Faure-Vincent , R. Calemczuk , Faculty of Medical Sciences, Universidade Nova de Lisboa, 4 4 1 C. Benoît , D. Peyrade and B. Dieny 1. SPINTEC, UMR-8191, Lisbon, Portugal CEA-INAC / CNRS / UJF-Grenoble / Grenoble-INP, Grenoble, France; 2. CEA, LETI, MINATEC Campus, 17 rue des Martyrs, 38054 Grenoble Cedex 9, Grenoble, France; 3. CEA- 3:30 INAC/SPrAM, UMR-5819, CEA-INAC/CNRS/UJF-Grenoble1, BH-09. Detection of E. coli using an electromagnetic trap. F. Li 1 and 38054 Grenoble, Grenoble, France; 4. CNRS-LTM UMR 5129, J. Kosel11. Computer, Electrical and Mathematical Sciences & CNRS/UJF-Grenoble1, Grenoble, France Engineering, King Abdullah University of Science and Technology, Thuwal, Saudi Arabia 72 PROGRAM PROGRAM 73

3:42 BP-03. Quantifying Spin Hall Angle of Pd from Spin Pumping and Microwave Photoresistance. X. Tao1,2, Z. Feng1,2, L. Sun1,2, BH-10. Clumping and chaining of bio-magnetic nanoparticles causes B. You1,2 and H. Ding1,21. Physics Department, Nanjing changes in their magnetic properties. K. Livesey1 and 1 University, Nanjing, Jiangsu, China; 2. National Laboratory of R. Camley 1. Department of Physics & UCCS Biofrontiers Solid State Microstructures, Nanjing University, Nanjing, Jiangsu, Center, University of Colorado at Colorado Springs, Colorado China Springs, CO

BP-04. Dynamical spin injection from Ni80Fe20 layer into bismuth 3:54 layer. E. Hiroyuki1, A. Yuichiro1, S. Eiji2, F. Yuki3, S. Teruya1 and 1 BH-11. Synthesis and magnetic properties of positive and negative S. Masashi 1. Graduate School of Engineering Science, Osaka charged nanostructured media for biomedical University, Toyonaka, Osaka, Japan; 2. Graduate School of applications.C. Dannangoda1, M. Hobosyan1, B. Ermolinsky2 and Engineering, Osaka City University, Osaka, Osaka, Japan; 3. K. Martirosyan1,21. Physics and Astronomy, University of Texas at Graduate School of Mmedia Science and Engineering, University Brownsville, Brownsville, TX; 2. Biomedical, University of Texas of Electro-Communications, Chofu, Tokyo, Japan at Brownsville, Brownsville, TX BP-05. Tuning of the spin pumping in yttrium iron garnet/Au bilayer 1 2 4:06 system by fast thermal treatment. L. Jin , D. Zhang , H. Zhang1, Q. Yang1, X. Tang1, Z. Zhong1 and J. Xiao31. State BH-12. Magnetic multicomponent nanoparticles CuxNi1-xFe2O4 for Key Laboratory of Electronic Thin Films and Integrated Devices, 1 2 3 biomedical applications. A. Bingolbali , N. Dogan , Z. Yesil and University of Electronic Science and Technology of China, 4 M. Asilturk 1. Bioengineering, Yildiz Technical University, Chengdu, Sichuan, China; 2. Department of Electrical and Istanbul, Turkey; 2. Physics, Gebze Institute of Technology, Computer Engineering, University of Delaware, Newark, DE; 3. Kocaeli, Turkey; 3. Chemistry, Akdeniz University, Antalya, Department of Physics and Astronomy, University of Delaware, Turkey; 4. Materials Science and Engineering, Akdeniz Newark, DE University, Antalya, Turkey

BP-06. Effect of Damping Constant on Spin Voltage of 4:18 1,2 2 La0.7Sr0.3MnO3/Platinum Bilayer Film. G. Luo , C. Chang and 1 BH-13. Ferromagnetic FePt/Au Core/Shell Nanoparticles Prepared J.G. Lin 1. Center for Condensed Matter Sciences, National via Solvothermal Annealing. N. Poudyal1, K.H. Gandha1, Taiwan university, Taipei, Taiwan; 2. Physics, National Taiwan J. Liu1, H. Arami1 and J. Liu11. Department of Physics, University University, Taipei, Taiwan of Texas at Arlington, Arlington, TX BP-07. All-metal lateral spin valve operated by spin pumping. N. Kuhlmann1, C. Swoboda1,2, L. Feiler1, A. Vogel1, T. Matsuyama1 and G. Meier1,21. Institute for Applied Physics, University of Hamburg, Hamburg, Germany; 2. The Hamburg TUESDAY EXHIBIT HALL Centre for Ultrafast Imaging, Hamburg, Germany AFTERNOON 2:30 BP-08. Mode dependence for ISHE and AHE. M. Seo1, S. Kim1,2, C. Moon2,3, B. Min3, K. Lee2,4 and S. Park11. Division of Session BP Materials Science, Korea Basic Science Institute, Daejeon, Republic of Korea; 2. Department of Materials Science and SPIN PUMPING AND SPIN INJECTION Engineering, Korea University, Seoul, Republic of Korea; 3. (Poster Session) Korea Institute of Science and Technology, Seoul, Republic of Weigang Wang, Chair Korea; 4. KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul, Republic of Korea

BP-01. Spin pumping in nanometer-sized lateral devices consisting of 1,2 1 Permalloy / Cu / Pt. T. Yamamoto1, T. Seki1 and K. Takanashi11. BP-09. Semicircular Rashba arc spin polarizer. Z. Siu , M. B.A. Jalil 2 Institute for Materials Research, Tohoku Univ., Sendai, Japan and S. Tan 1. NUS Graduate School for Integrative Sciences and Engineering, National University of Singapore, Singapore, Singapore; 2. Advanced Concepts and Nanotechnology, Data BP-02. All-electrical spin pumping in a Rashba-Dresselhauss spin- Storage Institute, Singapore, Singapore orbit coupling system.C. Ho1,2, M.B. Jalil1 and S. Tan1,21. Deparment of Electrical and Computer Engeering, National University of Singapore, Singapore; 2. Data Storage Institute, BP-10. Investigation of Magnetic Proximity Effect in Ta/YIG Bilayer 1,2 1 2 1 Singapore, Singapore Hall Bar Structure. Y. Yang , B. Wu , K. Yao and Y. Wu 1. Electrical and Computer Engineering, National University of Singapore, Singapore, Singapore; 2. Institute of Materials Research and Engineering, Singapore, Singapore 74 PROGRAM PROGRAM 75

BP-11. Observation of spin injection and inverse spin-Hall effect in TUESDAY EXHIBIT HALL 1 2 2 La0.67Sr0.33MnO3 D. Kikuchi , Y. Kajiwara , Y. Shiomi , 2 1,3 AFTERNOON Y. Fujikawa and E. Saitoh 1. Institute for Materials Research 2:30 and WPI-AIMR, Tohoku University, Sendai, Japan; 2. Institute for Materials Research, Tohoku University, Sendai, Japan; 3. Advanced Science Research Center, Japan Atomic Energy Agency, Session BQ Tokai, Japan HYSTERESIS MODELING (Poster Session) BP-12. Large effect of Peltier cooling on nonlocal spin signals in Co- Denise Hinzke, Chair based Heulser alloys/Cu lateral spin valves. K. Yamasaki1, S. Oki1, K. Tanikawa1, S. Yamada1, M. Miyao1,2 and K. Hamaya11. Department of Electronics, Kyushu University, BQ-01. Biaxial Preisach-type Model for Sequential Application of 1 1,2 Fukuoka, Japan; 2. CREST, Japan Science and Technology Orthogonal Fields. H. ElBidweihy , C.D. Burgy , E. Della 1 1 Agency, Tokyo, Japan Torre and L.H. Bennett 1. Department of Electrical and Computer Engineering, The George Washington University, Washington, DC; 2. Carderock Division, Naval Surface Warfare BP-13. Large spin-accumulation effect in Co2Fe1-xMnxSi/Cu non-local Center, West Bethesda, MD spin-valve devices. Y. Sakuraba1, K. Saito1, M. Ueda1, H. Shimizu1, Y. Fujun1, T. Koda1, S. Bosu1 and K. Takanashi11. Institute for Materials Research, Tohoku University, Sendai, BQ-02. A phenomenological hysteresis model described by transition 2 Miyagi, Japan probability function of magnetization process.C. Lee , K. Miyata2, C. Kaido3 and T. Matsuo11. Dept. Electrical Engineering, Kyoto University, Kyoto, Japan; 2. Hitachi, Ltd., BP-14. Hanle effect with in-plane magnetic fields in metallic lateral Hitachi, Japan; 3. Kitakyushu National College of Technology, 1,2 4 spin valves.J. Rojas Sanchez , P. Laczkowski , W. Savero Kitakyushu, Japan Torres2,3, M. Cubukcu1, L. Vila2,3, A. Marty2,3, M. Jamet2,3 and J. Attane2,31. Spintec, CEA, Grenoble, Rhone Alpes, France; 2. INAC/SP2M, CEA, Grenoble, Rhone Alpes, France; 3. Universite BQ-03. Micromagnetic Study of Soft Magnetic Properties of Granular 1 1 Joseph Fourier, Grenoble, Rhone Alpes, France; 4. Unite Mixte Ferromagnetic Materials. S. Couture , M.A. Escobar , 1 1 de physique, CNRS/Thales, Paris, Paris, France E.E. Fullerton and V. Lomakin 1. Center for Magnetic Recording Research, Department of Electrical and Computer Engineering, University of California, San Diego, CA BP-15. Kondo-suppressed spin accumulation in nanoscopic non-local spin transport devices. L. O’Brien1,2, D. Spivak3, M. Erickson3, H. Ambaye4, R.J. Goyette4, V. Lauter4, P.A. Crowell3 and BQ-04. Generalized Stoner-Wohlfarth model accurately describing C. Leighton11. Chemical Engineering and Materials Science, the switching processes in pseudo-single and multi domain 1 1 University of Minnesota, Minneapolis, MN; 2. Thin Film ferromagnetic particles. D. Cimpoesu , L. Stoleriu and 1 Magnetism, University of Cambridge, Cambridge, United A. Stancu 1. Physics, Alexandru Ioan Cuza University of Iasi, Kingdom; 3. School of Physics and Astronomy, University of Iasi, Romania Minnesota, Minneapolis, MN; 4. Spallation Neutron Source, Oak Ridge National Laboratory, Oak Ridge, TN BQ-05. Tracking individual wires contribution on the FORC diagram for magnetic nanowire arrays samples.C. Dobrota1 and 1 BP-16. Observation of Hanle- and inverted Hanle-like signals in 3- A. Stancu 1. Department of Physics, Alexandru Ioan Cuza terminal devices generated by Coulomb correlations in University of Iasi, Iasi, Romania paramagnetic impurities. O. Txoperena1, Y. Song2, M. Gobbi1, 1 1,3 1 1,4 2,5 A. Bedoya-Pinto , F. Golmar , X. Sun , L. Hueso , H. Dery BQ-06. Hybrid models of hysteresis for mixed hysteretic loops in 1,4 and F. Casanova 1. CIC nanoGUNE, Donostia, Gipuzkoa, Spain; heterogenous magnetic materials.M. Dimian2, P. Andrei1 and 2. Department of Physics, University of Rochester, Rochester, NY; G. Mixon11. ECE Department, Florida State University, 3. I.N.T.I.-CONICET, Buenos Aires, Argentina; 4. IKERBASQUE, Tallahassee, FL; 2. EECS Department, Stefan cel Mare Bilbao, Basque Country, Spain; 5. Department of Electrical and University, Suceava, Romania Computer Engineering, University of Rochester, Rochester, NY

BQ-07. Investigation and Modeling of Two-Dimension Vectorial Magnetic Hysteresis Properties for Magneto-Rheological Fluid Material.J. Zeng1,2, Y. Guo2, Z. Lin2 and J. Zhu21. School of Electrical Engineering, Shenyang University of Technology, Shenyang, Liaoning, China; 2. FEIT, University of Technology, Sydney, Sydney, NSW, Australia 76 PROGRAM PROGRAM 77

BQ-08. Magnetization reversal modes in rectangular nanoparticles: TUESDAY EXHIBIT HALL controlling the number of magnetic vortices. R.A. Escobar1, 1 1 1 AFTERNOON N.M. Vargas , S. Allende and D. Altbir 1. Physics, Universidad 2:30 de Santiago de Chile, Santiago, Chile Session BR BQ-09. Modeling of Magnetization Curves for Systems with the First Order Phase Transition. Y. Melikhov1, R.L. Hadimani2 and SOFT MAGNETIC THIN FILMS I A. Raghunathan31. Wolfson Centre for Magnetics, School of (Poster Session) Engineering, Cardiff University, Cardiff, United Kingdom; 2. Manh-Huong Phan, Chair Department of Electrical and Computer Engineering, Iowa State University, Ames, IA; 3. GE Global Research, JFWTC, Whitefield, Bangalore, India BR-01. Characterization of soft amorphous Co-Zr-Ta-B films on CMOS packaging substrates for in-package power inductor applications. H. Wu1, S. Zhao1, D.S. Gardner2 and H. Yu11. Ira A. BQ-10. First-Order Reversal Curve Study of SmFe2 Melt-Spun Fulton Schools of Engineering, Arizona State University, Tempe, 1 1 Ribbons. M.C. Grijalva Castillo , C.R. Santillán Rodríguez and AZ; 2. Intel Labs, Intel Corp., Santa Clara, CA J.A. Matutes Aquino11. Física de Materiales, Centro de Investigación en Materiales Avanzados, S.C., Chihuahua, Chihuahua, Mexico BR-02. Optimization of high frequency characteristics in Co-Ta thin films. H.W. Chang1, L.C. Chuang2, C.W. Shih2, W.C. Chang2 and D.S. Xue31. Department of Physics, Tunghai University, BQ-11. A simplified model of ferromagnetic sheets considering the Taichung, Taiwan; 2. Department of Physics, National Chung magnetization dynamics utilizing the saturation wave model. Cheng University, Chia-Yi, Taiwan; 3. The Key Laboratory for 1 2 2 2 1 S. Steentjes , S. Zirka , Y. Moroz , E. Moroz and K. Hameyer 1. Magnetism and Magnetic Materials of Ministry of Education, Institute for Electrical Machines, RWTH Aachen University, Lanzhou University, Lanzhou, China Aachen, Germany; 2. Dnepropetrovsk National University, Dnepropetrovsk, Ukraine BR-03. Magnetic and electrical properties of nanogranular CoFe- YSZ films. G. Hao1, H. Zhang1 and X. Tang11. University of BQ-12. Compact Modeling of Perpendicular Nanomagnetic Logic Electronic Science and Technology, Chengdu, People’s Republic 1 1 based on Threshold Gates. S. Breitkreutz , I. Eichwald , of China, China J. Kiermaier1, G. Csaba2, D. Schmitt-Landsiedel1 and M. Becherer11. Lehrstuhl für Technische Elektronik, Technische Universität München, Munich, Germany; 2. Center for Nano BR-04. Analysis of anisotropy of FeCoAlON alloy films with stripe 1 1 1 1 1 1 Science and Technology, University of Notre Dame, Notre Dame, domain.F. Wei , M. Liu , F. Zheng , Y. Lou , D. Wu , Y. Wang , 1 1 2 3 IN J. Cao , J. Bai , K. Alexander S. and D. Wei 1. Key Laboratory for Magnetism and Magnetic Materials of the Ministry of Education, Lanzhou University, Lanzhou 730000, Gansu, China; BQ-13. Angular dependence of the coercivity and remanence of 2. Ioffe Physico-Technical Institute of Russian Academy of 1 cylindrical diameter modulated nanowires.F. Tejo , N. Vidal- Sciences, St. Petersburg 194021, Russian Federation; 3. Key 1 1 Silva and J. Escrig 1. Departamento de Física, Universidad de laboratory for Advanced Materials Ministry of Education, Santiago Chile, Santiago, Chile Tsinghua University, Beijing 100084, China

BQ-14. A dynamic model for hysteresis in magnetostrictive devices. BR-05. Statistical distribution of single domain wall velocities in 1 M. Trapanese 1. DEIM, Università di Palermo, Palermo, Italy circular magnetic microwire. A. Jiménez-Villada11. Instituto de ciencia de Materiales de Madrid (ICMM), Madrid, Spain BQ-15. Kondorski Reversal in Magnetic Nanowires. R. Skomski1, 2 1 1 E. Schubert , A. Enders and D.J. Sellmyer 1. Physics and BR-06. Existence of spontaneous rectangular hysteresis loop with Astronomy, University of Nebraska, Lincoln, NE; 2. Electrical very high uniaxial anisotropy in sputtered NiFe films without Engineering, University of Nebraska, Lincoln, NE biasing field.P. Saravanan1,2, J. Hsu1, C.L. Tsai1, C.Y. Koo1, J.C. Wu3 and C.K. Lo41. Physics, National Taiwan University, BQ-16. Magnetic Properties Modeling of SMC Materials Using Two- Taipei, Taiwan; 2. Defence Metallurgical Research Laboratory, dimensional Vector Hybrid Hysteresis Model.D. Li1, F. Liu1, Hyderabad, India; 3. Physics, National Chang Hua University of Y. Li 1, Z. Zhao1 and S. Zhang11. Province-Ministry Joint Key Education, Chang Hua, Taiwan; 4. Physics, National Taiwan Laboratory of Electromagnetic Field and Electrical Apparatus Normal University, Taipei, Taiwan Reliability, Hebei University of Technology, Tianjin, China BR-07. Electrodeposition of FeCoCd films with in-plane uniaxial magnetic anisotropy for microwave applications.E. Feng1, Z. Wang1, H. Du1, J. Wei1, D. Cao1, Q. Liu1 and J. Wang11. Key Laboratory for Magnetism and Magnetic Materials of the Ministry of Education, Lanzhou University, Lanzhou, China 78 PROGRAM PROGRAM 79

BR-08. Quasi magnetic isotropy and microwave performance of TUESDAY EXHIBIT HALL FeCoB multilayers laminated by uniaxial anisotropic films. 1,2 1 1 1 1 1 3 AFTERNOON S. Li , H. Du , Y. Zhang , Q. Xue , X. Gao , W. Shao , Z. Zhou , 2:30 T. Nan3 and N. Sun31. College of Physics Science, Qingdao University, Qingdao, Shandong, China; 2. National Laboratory of Solid State Microstructures, Nanjing University, Nanjing, China; Session BS 3. Electrical and Computer Engineering Department, TUNNEL MAGNETORESISTANCE I Northeastern University, Boston, MA (Poster Session) Kay Yakushiji, Chair BR-09. The Dependence of Transverse Susceptibility on Magnetic

Field at Low and High Frequencies in Co/SiO2 Multilayers. 1 1 1 1 M. Contreras , V. Rodríguez , R. Matarranz and J.F. Calleja 1. BS-01. Full-Heusler Co2FeSi alloy thin films with perpendicular 1 Applied Physics, University of Oviedo, Oviedo, Asturias, Spain magnetic anisotropy induced by MgO-interface. Y. Takamura , T. Suzuki1, Y. Fujino1 and S. Nakagawa11. Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan BR-10. Structure, Property, Processing Correlations in CoFe / SiO2 Thin Films.P. Ohodnicki1,2, V. Sokalski3, V. DeGeorge2, M. McHenry2, D. Laughlin2 and J. Kortright41. Functional BS-02. Process induced damage by C-O based etching chemistries Materials Development Division, National Energy Technology and its recovery for a CoFeB-MgO magnetic tunnel junction 1 Laboratory, Pittsburgh, PA; 2. Materials Science and with perpendicular magnetic easy-axis. K. Kinoshita , 2 2 2 1 Engineering, Carnegie Mellon University, Pittsburgh, PA; 3. H. Honjo , K. Tokutome , S. Miura , M. Murahata , 3 1 1 1,3 1 Electrical and Computer Engineering, Carnegie Mellon K. Mizunuma , H. Sato , S. Fukami , S. Ikeda , N. Kasai and 1,3 University, Pittsburgh, PA; 4. Lawrence Berkeley National H. Ohno 1. Center for Spintronics Integrated Systems, Tohoku Laboratory, Berkeley, CA University, Sendai, Miyagi, Japan; 2. Green Platform Research Laboratories, NEC Corporation, Tsukuba, Ibaraki, Japan; 3. Laboratory for Nanoelectronics and Spintronics, Research BR-11. Tuning of permeability spectra in FeCo-TiO2 nanogranular Institute of Electrical Communication, Tohoku University, Sendai, 1 1 1 1 films.Y. Wang , H. Zhang , L. Wang and F. Bai 1. State Key Miyagi, Japan Laboratory of Electronic Thin Films and Integrated Devices, University of Electronic Science and Technology of China, Chengdu, China BS-03. Coupling of Co/Pt Multi-layers with FeCoB for Increased Annealing Stability in Perpendicular Magnetic Tunnel Junctions. V.M. Sokalski1, M.T. Moneck1, D. Bromberg1 and BR-12. Effect of current density on magnetic properties of J. Zhu11. Electrical and Computer Engineering, Carnegie Mellon, electrodeposited thin Fe-Ni films prepared in a citric-acid- Pittsburgh, PA based bath. T. Shimokawa1, T. Yanai1, Y. Watanabe1, M. Nakano1 and H. Fukunaga11. Nagasaki University, Nagasaki, Japan BS-04. Interfacial perpendicular magnetic anisotropy in CoFeB/MgO structures with various underlayers. Y. Oh 1,2, K. Lee1,2, BR-13. Simulation on Hysteresis Loop of Amorphous FeB Soft J. Jeong3,4 and B. Park1,21. Materials Science and Engineering, 1 1 2 Magnetic Film. J. Li , D. Wei and F. Masaaki 1. School of Korea Advanced Institute of Science and Technology (KAIST), Materials Science and Engineering, Tsinghua University, Beijing, Daejeon, Republic of Korea; 2. KI for the Nanocentury, Korea China; 2. Faculty of Science and Engineering, Chuo University, Advanced Institute of Science and Technology (KAIST), Daejeon, Tokyo, Japan Republic of Korea; 3. Materials Science and Engineering, Chungnam National University, Daejeon, Republic of Korea; 4. BR-14. Engineering damping by dilute Gd doping in soft magnetic Graduate School of Green Energy Technology, Chungnam FeGd thin films. W. Zhang1, S. Jiang1, P. Wong2, Y. Wang1, National University, Daejeon, Republic of Korea K. Wang2, M. de Jong2, W. van der Wiel2, G. van der Laan3 and 1 Y. Zhai 1. Department of Physics, Southeast University, Nanjing BS-05. Embedded Fe nanoparticles into the MgO layer of 211189, China; 2. NanoElectronics Group, MESA+ Institute for CoFeB/MgO/CoFeB perpendicular magnetic tunnel Nanotechnology, P.O. Box 217, University of Twente, 7500 AE junctions.C. Lee1,2, L. Ye1, C. Chiou1,3, Y. Chang3 and T. Wu1,21. Enschede, Netherlands; 3. Diamond Light Source, Magnetic Taiwan SPIN Research Center, National Yunlin University of Spectroscopy Group, Didcot OX11 0DE, United Kingdom Science and Technology, Douliou, Taiwan; 2. Graduate School of Materials Science, National Yunlin University of Science and Technology, Douliou, Taiwan; 3. Graduate School of Electronic BR-15. Study of electronic and ionic structure of glassy Fe76Si9B10P5 alloy by Ab Initio simulation. Y. Wang 1, A. Makino1, Y. Liang2 and Optoelectronic Engineering, National Yunlin University of and Y. Kawazoe21. Institute for Materials Research, Tohoku Science and Technology, Douliou, Taiwan University, Sendai, Miyagi Prefecture, Japan; 2. New Industry Creation Hatchery Center, Tohoku University, Sendai, Miyagi BS-06. CoFe and CoFeB as seed layers used in MgO/ Co2FeSi Prefecture, Japan Heusler alloy Tunnel Junctions. P.J. Chen1, J.W. Lau1, G. Feng1 and R.D. Shull11. National Institute of Standards and Technology, Gaithersburg, MD 80 PROGRAM PROGRAM 81

BS-07. Influences of hydrogen on eletric and magnetic properties of BS-14. High resolution mapping of non-patterned MRAM film perpendicular MTJs. J. Jeong1,2, Y. Kim2, W. Kim2, S. Park2 and stacks. D. Kjaer1,2, H.H. Henrichsen2,1, J.W. Chenchen3, T. Endoh1,31. Graduate School of Engineering, Tohoku University, O. Hansen2,4, P.F. Nielsen1 and D.H. Petersen21. Capres A/S, Kgs. Sendai, Miyagi, Japan; 2. Semicnductor R&D Center, Samsung Lyngby, Denmark; 2. DTU Nanotech, Technical University of Electronics Co.,Ltd, Hwasung, Gyeonggi-do, Republic of Korea; Denmark, Kgs. Lyngby, Denmark; 3. Data Storage Institute, 3. Center of Innovative Integrated Electronic Systems, Tohoku Singapore, Singapore; 4. CINF, Technical University of Denmark, University, Sendai, Miyagi, Japan Kgs. Lyngby, Denmark

BS-08. Observation of perpendicular magnetic anisotropy in BS-15. Switching Distributions in Magnetic Tunnel Junction

[Co2MnSi/Pd]n superlattice formed by ultrathin FeCo- Nanopillars Measured with a Scanning Probe. 1 1 1 insertion technique between Co2MnSi and Pd layers. S.K. Piotrowski , S.D. Oberdick and S.A. Majetich 1. Physics, Y. Fujino1, Y. Kubota1, Y. Takamura1, Y. Sonobe2 and Carnegie Mellon University, Pittsburgh, PA S. Nakagawa11. Physical Electronics, Tokyo Institute of Technology, Meguro-ku, Tokyo, Japan; 2. Yokohama Research BS-16. XRR, HRTEM and ToF-SIMS characterization of thin Institute, Samsung, Yokohama, Kanagawa, Japan Ta/CoFeB/MgO/Ta stacks with PMA. A. Lamperti1, L. Nasi2, L. Lazzarini2, I. Barisic3,4, B. Ocker5, R. Mantovan1 and BS-09. Annealing temperature dependence of magnetoresistance in D. Ravelosona31. Laboratorio MDM, IMM-CNR, Agrate Brianza, CoFeB/MgO/CoFeB perpendicular magnetic tunnel junctions. MB, Italy; 2. CNR-IMEM, Parma, PR, Italy; 3. Institut K. Nishimura1, H. Okuyama1, H. Maehara1, T. Seino1 and d’Electronique Fondametalé, CNRS, UMR 8622, Orsay, France; K. Tsunekawa11. Canon Anelva, Kawasaki, Kanagawa, Japan 4. Université Paris-Sud, Orsay, France; 5. Singulus Technology AG, Kahl am Main, Germany BS-10. Characterization of Ultrathin Fe–Co Layer Grown on Amorphous Co–Fe–B by In situ Reflective High-Energy Electron Diffraction. H. Hosoya1,3, H. Maehara1,3, Y. Nagamine1,3, K. Tsunekawa1,3, V. Zayets2 and S. Yuasa2,31. Process Development Center, Canon ANELVA, kanagawa, Japan; TUESDAY EXHIBIT HALL 2. Spintronics Research Center, National Institute of Advanced AFTERNOON Industrial Science and Technology (AIST), Ibaraki, Japan; 3. 2:30 Japan Science and Technology Agency (JST), CREST, Saitama, Japan Session BT HEAT-ASSISTED MAGNETIC RECORDING BS-11. The dipolar interaction in CoFeB/MgO/CoFeB perpendicular magnetic tunnel junction. C. Cheng1, C. Tsai2, Y. Weng1 and (Poster Session) G. Chern11. Department of Physics, National Chung Cheng Simon Greaves, Chair University, Chia-Yi, Taiwan; 2. Department of Engineering and Management of Advanced Technology, Chang Jung Christian BT-02. Alloying effect of Cr-based seed layer on control of sheet University, Tainan, Taiwan texture of MgO and thermal conductivity. H. Yakabe1, S. Hinata2, S. Saito2 and M. Takahashi21. Hitachi metals, Yasugi, BS-12. New post-oxidation process of Mg by using thermal gas Shimane, Japan; 2. Electronic Engineering, Tohoku University, cracker. K. Yakushiji1,2, M. Konoto1, T. Nozaki1, A. Fukushima1, Sendai, Miyagi, Japan H. Kubota1 and S. Yuasa11. Spintronics Research Center, AIST, Tsukuba, Japan; 2. PRESTO-JST, Kawaguchi, Japan BT-03. Analysis of Unswitched Grains in Thermally Assisted Magnetic Recording. S. Greaves1, H. Muraoka1 and Y. Kanai21. BS-13. Annealing effects of degree of order in Co-Ti-Fe-Ga films. RIEC, Tohoku University, Sendai, Japan; 2. IEE, Niigata Institute R.Y. Umetsu1,2, A. Okubo3, M. Nagasako3, M. Ohtsuka4 and of Technology, Kashiwazaki, Japan R. Kainuma31. Institute for Materials Research, Tohoku University, Sendai, Japan; 2. Japan Science and Technology BT-04. Effect of Ag addition to L10 FePt and L10 FePd films grown Agency-Precursory Research for Embryonic Science and by molecular beam epitaxy.Y. Tokuoka1, Y. Seto1, T. Kato1 and Technology, Tokyo, Japan; 3. Department of Materials Science, S. Iwata11. Department of Quantum Engineering, Nagoya Tohoku University, Sendai, Japan; 4. Institute of Multidisciplinary University, Nagoya, Japan Research for Advanced Materials, Tohoku University, Sendai, Japan BT-05. Curie temperature and magnetic anisotropy for L10 type Fe- Pt-Cu single crystal films. T. Moriya1,2, H. Nakata1,2, K. Komiyama1,2, S. Okamoto3, N. Kikuchi3, O. Kitakami3 and T. Shimatsu1,41. FRIS, Tohoku University, Sendai, Japan; 2. Fuji Electric Co., Ltd., Tokyo, Japan; 3. IMRAM, Tohoku University, Sendai, Japan; 4. RIEC, Tohoku University, Sendai, Japan 82 PROGRAM PROGRAM 83

BT-06. Thermal Modeling of Heat Assisted Magnetic Recording BT-16. Enhancement of perpendicular c-axis alignment in 1 1 1 1 1 (HAMR). D. Gabay , V. Krishna , Q. Ding , M. Menarini , nonepitaxially grown L10 FePt thin films. T. George , P.R. Bandaru1 and V. Lomakin11. University of California, San R. Zhang1, X. Li1 and D.J. Sellmyer11. Department of Physics and Diego, La Jolla, CA Astronomy, University of Nebraska, Lincoln, NE

BT-07. Columnar FePt based media for HAMR. O. Mosendz1, BT-17. Addition of Ag and Au to reduce ordering temperature of very D. Weller1, O. Hellwig1, H. Richter1, S. Pisana1, J. Reiner1, thin FePt films on MgO underlayer. T. Kawahara1, M. Tanaka1 T. Santos1 and S. Jain11. San Jose Research, HGST, a Western and S. Nakagawa11. Department of Physical Electronics, Tokyo Digital Company, San Jose, CA Institute of Technology, Tokyo, Japan

BT-08. Highly (001) Textured L10 FePt-SiO2-C Films With Well- Isolated Small Grains by Using TiON Intermediate layer.H. Li1, K. Dong1, Y. Peng2, G. Ju2, G. Chow1 and J. Chen11. Materials Science and Engineering, National University of TUESDAY EXHIBIT HALL Singapore, Singapore, Singapore; 2. Seagate Technology, AFTERNOON Fremont, CA 2:30

Session BU BT-09. SNR impact comparison between Tc and Hk variation in HAMR. H. Li1 and J. Zhu11. Data Storage Systems Center, MAGNONICS Carnegir Mellon University, Pittsburgh, PA (Poster Session) Giovanni Carlotti, Chair BT-10. Analysis of Plasmon Resonances in Metallic Nanostructures in Proximity to Dielectric Objects with Application to Heat- Assisted Magnetic Recording.L. Hung1, P. McAvoy1, C. Krafft2 BU-01. Non-reciprocity of dipole-exchange spin waves in thin 1 and I. Mayergoyz11. Electrical and Computer Engineering, ferromagnetic films. M. Kostylev 1. School of Physics, The University of Maryland, College Park, MD; 2. Laboratory for University of Western Australia, Crawley, WA, Australia Physical Sciences, College Park, MD BU-02. Effect of the Spin-Twist Structure on the Spin-Wave

BT-11. Thermal analysis of ultrafast heating and magnetic switching Dynamics of the Fe55Pt45/Ni80Fe20 Exchange Spring Bilayers 1 1 1 1 1 1 with weak external field. J. Li , B. Xu , J. Zhang , K. Ye , with Varying Ni80Fe20 Thickness. S. Pal , S. Barman , 2 1 Z. Cen1 and H. Yang11. Data Storage Institute, Agency for O. Hellwig and A. Barman 1. Thematic Unit of Excellence on Science, Technology and Research, Singapore, Singapore Nanodevice Technology and Department of Condensed Matter Physics and Material Sciences, S. N. Bose National Centre For Basic Sciences, Kolkata, West Bengal, India; 2. San Jose BT-12. Generalized analytical approach for microwave assisted Research Center, HGST, a Western Digital Company, San Jose, magnetization reversal based on energy storage and CA dissipation. M. Elyasi1, V. Siddharth Rao1, C. Bhatia1 and H. Yang11. Electrical and Computer Engineering, National University of Singapore, Singapore, Singapore BU-03. Self-oscillation of standing spin wave in ring resonator with PID control.B. Peng1, Y. Urazuka1, S. Oyabu1, H. Chen1, H. Otsuki1, T. Tanaka1 and K. Matsuyama11. Faculty of BT-13. Microstructure and magnetic properties of B-added FePt-C Information Science and Electrical Engineering, Kyushu 1 thin films for heat-assisted magnetic recording media. W. Cui , University, Fukuoka, Fukuoka, Japan B. Varaprasad1, Y. Takahashi1, T. Shiroyama1 and K. Hono11. NIMS, Tsukuba, Japan BU-04. Numerical Calculation of Dispersion Relations of Plane Propagating Spin-Waves in a Two-Dimensional Magnonic BT-14. Switching field and critical frequency distributions on Crystal. D. Kumar1, J.W. Klos2, M. Krawczyk2 and A. Barman11. microwave assisted switching in Co/Pt nanodot array. Thematic Unit of Excellence on Nanodevice Technology and 1 1 1 1 M. Furuta , S. Okamoto , N. Kikuchi , O. Kitakami and Department of Condensed Matter Physics and Material Sciences, 2,3 T. Shimatsu 1. IMRAM, Tohoku University, Sendai, Miyagi, S. N. Bose National Centre For Basic Sciences, Kolkata, West Japan; 2. FRIS, Tohoku University, Sendai, Miyagi, Japan; 3. Bengal, India; 2. Faculty of Physics, A. Mickiewicz University in RIEC, Tohoku University, Sendai, Miyagi, Japan Poznan, Poznan, Poland

BT-15. Heat-assisted magnetic recording with patterned FePt BU-05. Excitation and Observation of Spinwaves by Femtosecond recording media using lollipop near field transducer. Laser Pulses. S. Yun1, C. Cho1 and S. Choe11. Department of 1 1 A. Ghoreyshi and R.H. Victora 1. Department of Electrical and Physics, Seoul National University, Seoul, Republic of Korea Computer Engineering, University of Minnesota, Minneapolis, MN 84 PROGRAM PROGRAM 85

BU-06. Investigation of Spin Pumping in YIG/Cu/Py using BU-13. Magnetization dynamics of magnonic crystals based on Ferromagnetic Resonance. Y. Hung1, G.M. Wolf1, A.D. Kent1, Permalloy ellipses. R. Dutra1, D.E. González-Chávez1, H. Chang2, Y. Sun2 and M. Wu21. Department of Physics, New T.L. Marcondes1, W.O. Rosa1, A.G. Vieira1 and R.L. Sommer11. York University, New York, NY; 2. Department of Physics, Centro Brasileiro de Pesquisas Físicas, Rio de Janeiro, Brazil Colorado State University, Fort Collins, CO BU-14. A diode-like spin wave filtering effect in asymmetrically BU-07. Effects of diffusion layer between inclusion and matrix on shape-modulated ferromagnetic nanowires. H. Piao1,3, magnon band gap in two-dimension magnonic J. Shim2, D. Djuhana2,4, S. Lee2 and D. Kim21. College of Science, crystal.Q. Wang1, L. Jin1, X. Tang1, F. Bai1, H. Zhang1 and China Three Gorges University, Yichang, 443002, China; 2. Z. Zhong11. University of Electronic Science and Technology of Department of Physics, Chungbuk National University, Cheongju, China, Chengdu, Sichuan, China 361-763, Republic of Korea; 3. School of Materials Science and Engineering, Tsinghua University, Beijing, 100084, China; 4. Physics, University of Indonesia, Kampus Baru UI Depok, 16424, BU-08. Magnonic band structures in two-dimensional bi-component Indonesia magnonic crystals.M. Krawczyk1, S. Mamica1, . Mruczkiewicz1, J.W. Klos1, S. Tacchi2, M. Madami3, G. Gubbiotti2, G. Duerr4 and D. Grundler41. Faculty of Physics, Adam Mickiewicz University, BU-15. Ferromagnetic resonance in nano-structured surfaces for Poznan, Poland; 2. Istituto Officina dei Materiali (IOM)-CNR, microwave applications. N. Mikuszeit1, B. Viala1, J. Alarcon1, Perugia, Italy; 3. Dipartimento di Fisica, Università di Perugia, J. Michel1, C. Dubarry1, V. Brissoneau1, U. Ebels1, A. Marty1, Perugia, Italy; 4. Lehrstuhl für Physik funktionaler C. Gourgon2, A. Ferchichi2 and N. Vukadinovic31. INAC / SP2M / Schichtsysteme,, Garching, München, Germany NM, CEA, Grenoble, France; 2. Laboratoire des Technologies de la Microélectronique (LTM), CEA, Grenoble, France; 3. Dassault Aviation, St-Cloud, France BU-09. Detection of domain wall position and magnetization reversal in nanostructures using the magnon contribution to the resistivity.V. Nguyen1, W. Savero Torres2,4, P. Laczkowski3, BU-16. Confinement of Magnetostatic Forward Volume Waves in L. Vila2,4, C. Beigne2,4, L. Notin2,4, A. Marty2,4, C. Vergnaud2,4, Two-Dimensional Magnonic Crystals with Line M. Jamet2,4 and J. Attane2,31. Micro et Nanomagnetisme, Institute Defects*.K.H. Chi1, Y. Zhu1 and C.S. Tsai1,21. Electrical Neel, Grenoble, Rhone Alpes, France; 2. INAC/SP2M, CEA, Engineering and Computer Science, University of California, Grenoble, Rhone Alpes, France; 3. Unite Mixte de physique, Irvine, Irvine, CA; 2. Graduate Institute of Photonics and CNRS/Thales, Paris, Ile de France, France; 4. Universite Joseph Optoelectronics, National Taiwan University, Taipei, Taiwan Fourier, Grenoble, Rhone Alpes, France

BU-10. Frequency softening of collective modes in two-dimensional ferromagnetic antidot arrays. R. Zivieri1, P. Malagò1, L. Giovannini1, S. Tacchi2, G. Gubbiotti2 and A.O. Adeyeye31. TUESDAY EXHIBIT HALL Department of Physics and Earth Sciences, University of Ferrara, AFTERNOON Ferrara, Italy; 2. Department of Physics, University of Perugia, 2:30 Perugia, Italy; 3. Electrical and Computer Engineering, University of Singapore, Singapore, Singapore Session BV RARE EARTH PERMANENT MAGNETS II BU-11. Tunable Magnetic Anisotropy in Two-Dimensional Arrays of 1 1 2 1 (Poster Session) Ni80Fe20 Elements. S. Saha , S. Barman , J. Ding , A. Ganguly , A.O. Adeyeye2 and A. Barman11. Thematic Unit of Excellence on Nicoleta Lupu, Co-Chair Nanodevice Technology and Department of Condensed Matter Arti Kashyap, Co-Chair Physics and Material Sciences, S. N. Bose National Centre For Basic Sciences, Kolkata, West Bengal, India; 2. Information BV-01. Crystallographic anisotropic R-TM-N hard magnetic flakes. Storage Materials Laboratory, Department of Electrical and B. Cui1, M. Marinescu1 and J. Liu11. Electron Energy Computer Engineering, National University of Singapore, Corporation, Landisville, PA Singapore, Singapore

BV-02. Anisotropic Sm-Co/Fe composite particles by surfactant- BU-12. Ferromagnetic Resonance Critical Curves for Interacting assisted high energy ball milling. Y. Shen1,2, S. Leontsev1,2, Magnetic Nanowire Arrays.D. Cimpoesu1, J. Ding2, L. Stoleriu1, Z. Turgut3,2, A. Sheets3,2, N. Bryant4,2 and J. Horwath21. A. Stancu1, A. Adekunle2 and L. Spinu31. Faculty of Physics, Iasi University of Dayton, Dayton, OH; 2. Air Force Research University, Iasi, Romania; 2. Dept of Electrical & Computer Laboratory, Write-Patterson Air Force Base, OH; 3. UES Inc., Engineering, National University of Singapore, Singapore, Dayton, OH; 4. Wright State University, Dayton, OH Singapore; 3. AMRI/Physics, University of New Orleans, New Orleans, LA 86 PROGRAM PROGRAM 87

BV-03. FORC analysis of nanocrystalline Pr0.5Sm0.5Co5 BV-12. The partitioning of Cu and its effect on the interface exchange 1 2 α powders.C. Orquiz , M. Botello-Zubiate and J. Matutes interaction in Sm(Co,Cu)5/ -(Fe,Cu) nanocomposite magnets: Aquino21. Universidad Politécnica de la Región Ribereña, Miguel A first-principles study. X. Liu1, Z. Altounian2 and P. Liu11. Aleman, Tamaulipas, Mexico; 2. Física de Materiales, Centro de Physics, University of Texas at Arlington, Arlington, TX; 2. Investigación en Materiales Avanzados, Chihuahua, Chihuahua, physics department, McGill University, Montreal, QC, Canada Mexico α BV-13. Magnetic properties of isotropic and anisotropic SmCo5/ -Fe BV-04. Magnetic hardening mechanism of SmCo6.6Nb0.4 nanoflakes nanocomposite magnets with a layered structure simulated by prepared by surfactant-assisted ball milling method. Y. Li 1, micromagnetic theory.H. Fukunaga1, R. Horikawa1, T. Yanai1 M. Yue1, W. Liu1,2, Y. Liu1, D. Zhang1 and G.C. Hadjipanayis21. and M. Nakano11. Nagasaki University, Nagasaki, Japan College of Materials Science and Engineering, Beijing University of Technology, Beijing, China; 2. Department of Physics and Astronomy, University of Delaware, Newark, DE

BV-05. Textured PrCo5 nanoflakes with large coercivity prepared by TUESDAY PLAZA BALLROOM A surfactant-assisted ball milling.W. Zuo1, X. Zheng1, R. Wu1, AFTERNOON R. Liu1, F. Hu1, J. Sun1 and B. Shen11. State Key Laboratory for 2:30 Magnetism, Institute of Physics, Chinese Academy of Sciences, Beijing, China Session BW NANOPARTICLES IN ARRAYS I BV-06. Textured Pr2Fe14B flakes with a submicron or nanosize thickness prepared by surfactant-assisted ball milling.W. Zuo1, (Poster Session) X. Zheng1, R. Wu1, R. Liu1, F. Hu1, J. Sun1 and B. Shen11. State Tianlong Wen, Chair Key Laboratory for Magnetism, Institute of Physics, Chinese Academy of Sciences, Beijing, China BW-01. Self-assembled Nanocrystal Superlattic Membrane with Cubic FePt Nanoparticles at Liquid–air Interface. M. Zhou1, W. Li 1, M. Zhu1, D. Zhou1 and Y. Hou21. Central Iron and Steel BV-07. Sm2Fe17Nx nanoflakes prepared by surfactant assisted cryomilling. S. Zhang1,2, L. Liu1,2, J. Zhang1,2, J. Du1,2, W. Xia1,2, Research Institute, Beijing, China; 2. Peking University, Beijing, A. Yan1,2 and J. Liu31. Key Laboratory of Magnetic Materials and China Devices, Ningbo Institute of Material Technology and Engineering, Chinese Academy of Sciences, Ningbo, China; 2. BW-02. Effect of induced uniaxial magnetic anistorpy on Zhejiang Province Key Laboratory of Magnetic Materials and ferromagnetic resonance frequency of Fe-Co alloy Application Technology, Ningbo Institute of Material Technology nanoparticle/polystyrene nanocomposite. H. Kura1, K. Hata2, and Engineering, Chinese Academy of Sciences, Ningbo, China; O. Tadaaki2, M. Takahashi1 and T. Ogawa31. New Industry 3. Department of Physics, University of Texas at Arlington, Creation Hatchery Center, Tohoku University, Sendai, Miyagi, Arlington, TX Japan; 2. Samsung R&D Institute Japan Co.,Ltd., Yokohama, Kanagawa, Japan; 3. Department of Electronic Engineering,, BV-08. Structural and magnetic characterization of YCo5/FeNi Graduate School of Engineering, Tohoku University, Sendai, composite powder prepared by mechanical alloying and Miyagi, Japan subsequent annealing. G. Pokharel and S.R. Mishra Department of Physics, The University of Memphis, Memphis, BW-03. Magnetic properties of Co/Pt nano-ring arrays on carbon 1 1 TN 38152. G. Pokharel and S. Mishra 1. University of Memphis, nanotubes. S. Yoon1, S. Lee1, J. Kwon1, S. Lee1 and B. Cho11. Memphis, TN School of Materials Science and Engineering, Gwangju Institute of Science and Technology, Gwangju, Republic of Korea BV-09. Magnetic properties of anisotropic bulk MnBi/NdFeB hybrid 1 1 1 1 magnets. Y. Ma , X. Liu , V. Nguyen and J. Liu 1. University of BW-04. Crystal structure, interfacial bonding and magnetic properties Texas at Arlington, Arlington, TX of NiCoCu/Cu multilayer nanowires. H. Yang1, M. Zeng1 and R. Yu11. Materials Science and Engineering School, Beihang BV-10. Magnetic properties and thermal stability of MnBi/SmFeN University, Beijing, China hybrid bonded magnets. D. Zhang1, M. Yue1, W. Geng1, W. Liu1, 1 1 1 Q. Lu , Y. Liu and J. Zhang 1. College of Science and BW-05. Tunable magnetic anisotropy in electrodeposited Co-Ni alloy Engineering, Beijing university of technology, Beijing, China nanowires.F. Nasirpouri1, M. Nadi1, A. Samardak2, E. Sukovatitsina2, I. Litvintsev2, V. Pechnikov2 and 2 BV-11. Magnetic properties of nanocomposite MnBi/ Sm2Fe17Nx. L. Chebotkevich 1. Department of Materials Engineering, Y. Yang 1, X. Chen1, J. Wei1, R. Wu1, Y. Yang1, Y. Zhang1 and Sahand University of Technology, Tabriz, Islamic Republic of J. Yang11. School of Physics, Peking university, Beijing, China Iran; 2. School of Natural Sciences, Far Eastern Federal University, Vladivostok, Russian Federation 88 PROGRAM PROGRAM 89

BW-06. Microwave current power dissipation in thin composite films. BX-03. Parallelized micromagnetic solver for the efficient simulation M.P. Lasek1, L.N. Kotov1, K.A. Olga1, K.E. Yurii2 and of large patterned magnetic nanostructures.O. Bottauscio1 and S.V. Alexander21. RadioPhysics and Electronics, Syktyvkar State A. Manzin11. Istituto Nazionale di Ricerca Metrologica (INRIM), University, Syktyvkar, Komi, Russian Federation; 2. Voronezh Torino, Italy State Technical University, Voronezh, Russian Federation BX-04. A generalized tool for accurate time-domain separation of BW-07. Effect of high temperature on magnetoresistance excited modes in spin-torque oscillators. G. Siracusano1, A. La measurement in individual nickel nanowire. T. Ger1, Y. Chang1 Corte2 and G. Finocchio11. Department of Electronic and Z. Wei11. National Tsing Hua University, Hsinchu, Taiwan Engineering, Industrial Chemistry and Engineering, University of Messina, Messina, Italy; 2. Department of Informatic Engineering and Telecommunications, University of Catania, Catania, Italy BW-08. Magnetization reversal in multisegmented nanowires: Parallel and serial reversal modes. S. Allende1,2, N. Vargas1,2, D. Altbir1,2, V. Vega3, D. Görlitz4 and K. Nielsch41. Physics Department, BX-05. Maze energetics revealed by a large-scale two-dimensional Universidad de Santiago de Chile, Santiago, Chile; 2. Centro Ginzburg-Landau type simulation. K. Iwano1, C. Mitsumata2 para el Desarrollo de la Nanociencia y la Nanotecnología, and K. Ono11. IMSS, KEK, Tsukuba, Ibaraki, Japan; 2. National CEDENNA, Santiago, Chile; 3. Physics Department, Universidad Institute of Materials Science (NIMS), Tsukuba, Ibaraki, Japan de Oviedo, Oviedo, Spain; 4. Institute of Applied Physics, University of Hamburg, Hamburg, Germany BX-06. Computation of the magnetostatic interaction between linearly magnetized polyhedrons. D. Chernyshenko1, M. Albert1 BW-09. Microscopic insights into the magnetisation reversal process and H. Fangohr11. Engineering and the Environment, University in hexagonal nano-scaled antidot lattices.J. Gräfe1, F. Häring2, of Southampton, Southampton, United Kingdom U. Wiedwald2, P. Ziemann2, U. Nowak3, G. Schütz1 and E.J. Goering11. Schuetz, Max-Planck-Institute for Intelligent BX-07. VAMPIRE: open source software for atomistic simulation of Systems, Stuttgart, Germany; 2. Ulm University, Ulm, BW, magnetic materials. R.F. Evans1, W.J. Fan1, P. Chureemart1, Germany; 3. University of Konstanz, Konstanz, BW, Germany T.A. Ostler1, M.O. Ellis1 and R.W. Chantrell11. Department of Physics, University Of York, York, England, United Kingdom BW-10. Concave nanomagnetic triangles: size and shape effect on the anisotropy and magnetization switching. T. Fisher1, BX-08. LaBonte’s method revisited.T. Schrefl1, L. Exl1 and S. Bance11. T. Barbosa1, D. Nosegbe1, A. Anferov1, I. Eremin2, I. Vasilevskiy2 Universityof Applied Sciences, St.Pölten, Austria and A. Kozhanov11. Physics and Astronomy, Georgia State University, Atlanta, GA; 2. National Research Nuclear University “MEPhI”, Moscow, Russian Federation BX-09. A fast multipole algorithm for demagnetizing field computation in finite element micromagnetics. D. Chernyshenko1, M. Albert1, M. Beg1, M. Bisotti1, W. Wang1 and H. Fangohr11. Engineering and the Environment, University of Southampton, Southampton, United Kingdom TUESDAY PLAZA BALLROOM A AFTERNOON BX-10. A mixed mid-point Runge-Kutta like scheme for the 2:30 integration of LLG. A. Rahim1, C. Ragusa1, B. Jan2 and O.U. Khan11. Department of Energy, Politecnico di Torino, Turin, Session BX Torino, Italy; 2. Department of Control and Computer MICROMAGNETICS - NUMERICAL METHODS Engineering, Politecnico di Torino, Turin, Torino, Italy

(Poster Session) BX-11. Stream Processing Approach to Finite Temperature Timothy Fal, Chair Micromagnetic Simulations. S. Fu1, S. Li1, R. Chang1, M. Escobar1, M. Menarini1 and V. Lomakin11. Center for BX-01. Application of a DOK Stress-Preisach Model through a Magnetic Recording Research, University of California, San Numerical Model. C. Burgy1,2, H. ElBidweihy2 and E. Della Diego, La Jolla, CA Torre21. Naval Surface Warfare Center, Carderock Division, West Bethesda, MD; 2. The George Washington University, Washington, DC

BX-02. An adaptive midpoint method time integrator for computational micromagnetics. D. Shepherd1, M. Heil2, M.D. Mihajlovic´1 and J.J. Miles11. NEST Group, School of Computer Science, The University of Manchester, Manchester, United Kingdom; 2. School of Mathematics, The University of Manchester, Manchester, United Kingdom 90 PROGRAM PROGRAM 91

TUESDAY PLAZA BALLROOM BC WEDNESDAY PLAZA BALLROOM F EVENING MORNING 6:00 8:30

Session YA Session CB EVENING SESSION: MAGNETISM IN ATOMIC DYNAMICS: SPIN TORQUE OSCILLATORS SYSTEMS AND TUNNEL JUNCTIONS Andrew Kent, Chair Andrei Slavin, Chair

6:00 8:30 YA-01. Chip-Scale Atomic Magnetometers for Biomagnetics and CB-01. Resonant properties of a domain wall and its magnetic NMR. (Invited) J. Kitching11. Time and Frequency Division, shadow. S. Lequeux1, J. Sampaio1, R. Matsumoto1, P. Bortolotti1, NIST, Boulder, CO A. Fukushima2, H. Kubota2, K. Yakushiji2, S. Yuasa2, V. Cros1 and J. Grollier11. Unité Mixte CNRS/Thales, Palaiseau, France; 2. AIST, Tsukuba, Japan

8:42 WEDNESDAY PLAZA BALLROOM BC MORNING CB-02. Spin waves in films, dots, and domain walls with 1 8:30 Dzyaloshinskii-Moriya interactions.F. Garcia-Sanchez , J. Kim1, A. Vansteenkiste2, P. Borys3 and R.L. Stamps31. Institut d’Electronique Fondamentale, CNRS / Univ. Paris-Sud, Orsay, Session CA France; 2. Department of Solid State Sciences, Ghent University, SYMPOSIUM ON SPIN INJECTION AND Ghent, Belgium; 3. School of Physics and Astronomy, University TRANSPORT IN ORGANIC MATERIALS of Glasgow, Glasgow, United Kingdom Ezekiel Johnston-Halperin, Chair 8:54

8:30 CB-03. Thermally-assisted magnetization reversal in nanomagnets with spin-transfer torque: energy space diffusive dynamics. CA-01. Towards Molecular Data Storage and Manipulations. (Invited) D. Pinna1, A.D. Kent1 and D.L. Stein1,21. Courant Institute of 1 J. Moodera 1. Physics Department, MIT, Cambridge, MA Mathematics, New York, NY; 2. Physics, New York University, New York, NY 9:06 CA-02. Spinterfaces: organic spintronics and beyond. (Invited) 9:06 1 M. Cinchetti 1. Department of Physics, University of CB-04. Thermally Induced Magnonic Spin Currents. (Invited) Kaiserslautern, Kaiserslautern, Germany D. Hinzke11. University of Konstanz, Konstanz, Germany

9:42 9:42

CA-03. Spin-dependent transport behaviour in C60-based spin valves CB-05. Automodulation effect in magnetic droplet spin torque 1 1 at room temperature. (Invited) X. Zhang , S. Mizukami , oscillators. S. Mohseni1,2, S.R. Sani1,2, S. Chung1,3 and 1 1 1 T. Kubota , Q. Ma and T. Miyazaki 1. WPI-AIMR, Tohoku J. Åkerman1,31. Materials Physics, KTH-Royal Institute of University, Sendai, Japan Technology, Kista, Sweden; 2. NanOsc AB, Kista, Sweden; 3. Department of Physics, University of Gothenburg, Gothenburg, 10:18 Sweden CA-04. Distinguishing Spin Relaxation Mechanisms in Organic Semiconductors. (Invited) N.J. Harmon1 and M.E. Flatté11. 9:54 Physics and Astronomy, University of Iowa, Iowa City, IA CB-06. Analytical Theory for Modulated Droplets. L. Bookman1 and M.A. Hoefer11. Mathematics, North Carolina State University, 10:54 Raleigh, NC CA-05. Tunneling anisotropic magnetoresistance and tunable tunnel barriers in organic spin valves. (Invited) G. Schmidt1,21. Institut für Physik, Universitaet Halle, Halle, Germany; 2. Center for materials research, Universität Halle, Halle, Germany 92 PROGRAM PROGRAM 93

10:06 WEDNESDAY PLAZA BALLROOM E CB-07. Confined dissipative droplet solitons in spin-valve nanowires MORNING with perpendicular magnetic anisotropy. E. Iacocca1, 8:30 R.K. Dumas1, L. Bookman2, M. Mohseni3, S. Chung1,3, M. Hoefer2 and J. Åkerman1,31. University of Gothenburg, Session CC Gothenburg, Sweden; 2. North Carolina State University, Raleigh, MULTILAYERS I: PERPENDICULAR NC; 3. Royal Institute of Technology, Stockholm, Sweden ANISOTROPY AND INTERFACE EFFECTS 10:18 Atsufumi Hirohata, Chair CB-08. Angular Dependence of Spin Wave Resonances Measured 8:30 with the Inverse Spin Hall Effect in YIG with a Ta Strip. 1 2 1 1 J. Sklenar , S. Lee , I.P. Nevirkovets , O. Chernyashevsky and CC-01. Magnetic Domain images of Soliton Injection and Propagation 1 J.B. Ketterson 1. Physics and Astronomy, Northwestern through a perpendicularly magnetized super lattice. J. Lee1, University, Evanston, IL; 2. Physics and q-Psi, Hanyang R. Mansell1, R. Lavrijsen1, D. Petit1, A. Fernandez-Pacheco1 and University, Seoul, Republic of Korea R. Cowburn11. Physics, University of Cambridge, Cambridge, United Kingdom 10:30 8:42 CB-09. Characterization of spin wave eigenmodes in magnetic tunnel junction nanopillars using field-modulated spin torque CC-02. Probing the magnetic properties of individual buried layers 1 2,1 ferromagnetic resonance. Y. Chen , A.M. Gonçalves , using solitons. D.C. Petit1, J. Lee1, R. Lavrijsen2, R. Mansell1, 1 1 3 1 I. Barsukov , L. Yang , J.A. Katine and I.N. Krivorotov 1. A. Fernández-Pacheco1 and R.P. Cowburn11. Physics department, Physics and Astronomy, University of California, Irvine, CA; 2. University of Cambridge, Cambridge, United Kingdom; 2. Center Centro Brasileiro de Pesquisas Físicas, Rio de Janeiro, RJ, for Nanomaterials, Eindhoven University of Technology, Brazil; 3. HGST Research Center, San Jose, CA Eindhoven, Netherlands

10:42 8:54 CB-10. Atomistic Spin Dynamics of Low-dimensional Magnets. CC-03. Lorentz microscopy of geometrically independent narrow 1 2 2 2 2 L. Bergqvist , A. Taroni , A. Bergman , C. Etz and O. Eriksson 1. domain walls in synthetic antiferromagnetically coupled Materials and Nano Physics, ICT, Kista, Sweden; 2. Physics and nanowires. S. McVitie1, R. Beacham1, S. Lepatadu2, M. Benitez Astronomy, Uppsala University, Uppsala, Sweden Romero1, A. Whiteside2, T.A. Moore2, D. McGrouther1, R.L. Stamps1 and C.H. Marrows21. Physics and Astronomy, 10:54 University of Glasgow, Glasgow, United Kingdom; 2. Physics and Astronomy, University of Leeds, Leeds, United Kingdom CB-11. Observation of spin wave resonance on spin torque oscillators having a perpendicularly magnetized free layer by mag-noise 9:06 measurements. S. Tamaru1, H. Kubota1, K. Yakushiji1, 1 1 1 1 R. Matsumoto , T. Nozaki , A. Fukushima , H. Imamura , CC-04. Control of Magnetic Properties Using Strain. (Invited) 1 1 1 1 T. Taniguchi , H. Arai , S. Tsunegi and S. Yuasa 1. Spintronics I.K. Schuller3,1, S. Wang2,3, J.G. Ramirez3,1 and J. De la Venta3,11. Research Center, National Institute of Advanced Industrial Physics-0319, UCSD, La Jolla,, CA; 2. Materials Science Science and Technology (AIST), Tsukuba, Ibaraki, Japan Program, UCSD, La Jolla, CA; 3. Center for Advanced Nanoscience (CAN), UCSD, La Jolla, CA 11:06 9:42 CB-12. Electrical Characterization of Spin Torque Nano-oscillators with a Perpendicular Free Layer and In-plane Polarizing CC-05. Stress Relaxation induced Enhancement of Nucleation Field in 1 1,2 1 Layer. D. Backes , F. Macià and A.D. Kent 1. Physics, New Co/Pt multilayers. K. Huang1 and C. Lai11. National Tsing Hua York University, New York, NY; 2. Grup de Magnetisme, University, Hsinchu, Taiwan Departament de Física Fonamental, Universitat de Barcelona, Barcelona, Spain 9:54

11:18 CC-06. Microwave properties and damping in [Pt/Co] multilayers with perpendicular anisotropy. A. Caprile1,2, M. Pasquale2, CB-13. Spin torque ferromagnetic resonance measurements on K. Michaela2, S. Lim3,4 and T. Lee31. INRiM, Torino, Italy; 2. 1 antiferromagnet/ferromagnet bilayers. T. Moriyama , DISAT, Politecnico di Torino, Torino, Italy; 3. Nano 1 1 1 1 M. Nagata , K. Tanaka , K. Kim and T. Ono 1. Institute for Semiconductor Engineering, Korea University, Seoul, Republic of Chemical Research, Kyoto University, Uji, Kyoto, Japan Korea; 4. Materials Science and Engineering, Korea University, Seoul, Republic of Korea 94 PROGRAM PROGRAM 95

10:06 WEDNESDAY PLAZA BALLROOM D MORNING CC-07. Interface induced orbital moment asymmetry in Co90Fe10/Ni multilayers with perpendicular anisotropy. J.M. Shaw1, 8:30 H.T. Nembach1 and T.J. Silva11. NIST, Boulder, CO Session CD 10:18 MRAM AND MAGNETIC LOGIC DEVICES I CC-08. Using Co/Ni multilayers for designing nanopillars for STT Pieter Visscher, Chair MRAM. M. Arora1, E. Montoya1, T. McKinnon1, A. Zamani2, 1 1 B. Heinrich and E. Girt 1. Department of Physics, Simon Fraser 8:30 University, Burnaby, BC, Canada; 2. Department of Physics and Astronomy, Uppsala University, Uppsala, Sweden CD-01. Large perpendicular magnetic anisotropy for Mn100-xGex epitaxial films prepared on a Cr buffer layer. A. Sugihara1, S. Mizukami1, Q. Ma1, A. Sakuma2, H. Tsuchiura2 and 10:30 T. Miyazaki11. WPI-AIMR, Tohoku University, Sendai, Japan; 2. CC-09. Perpendicular to in-plane anisotropy gradient in Co films Department of Applied Physics, Tohoku University, Sendai, Japan induced via tailored O-implantation profiles. B.J. Kirby1, 1 2 3 J.A. Borchers , E. Menéndez , J.F. Lopez-Barbera , 8:42 A. Vantomme2, K. Temst2 and J. Nogués3,41. Center for Neutron Research, National Institute of Standards and Technology, CD-02. Multi-level perpendicular MTJ STT-MRAM with controlled 1 1 Gaithersburg, MD; 2. Instituut voor Kern- en Stralingsfysica, KU edge field. Y. Zhou and Y. Huai 1. Avalanche Technology, Leuven, Leuven, Belgium; 3. ICN2 – Institut Catala de Fremont, CA Nanociencia i Nanotecnologia, Barcelona, Spain; 4. Institució Catalana de Recerca i Estudis Avançats (ICREA), Barcelona, 8:54 Spain CD-03. Interface anisotropy: simple fitting model. P.B. Visscher11. Physics, University of Alabama, Tuscaloosa, AL 10:42

CC-10. Control of the spin-flop transition in CoFeB/Ru ferrimagnetic 9:06 superlattices. A. Fernandez-Pacheco1, R. Mansell1, D. Mahendru1, D. Petit1, J.H. Lee1, A. Welbourne1, R. Lavrijsen1, CD-04. Magnetic field controlled InSb avalanche diodes for 1 1,2 1,2 R.P. Cowburn1, N.J. Steinke2, R. Dalgliesh2 and S. Langridge21. reconfigurable logic. (Invited) J. Chang , S. Joo , T. Kim , 2 3 4 2 1 1 University of Cambridge, Cambridge, United Kingdom; 2. ISIS, J. Hong , J. Song , H. Lee , K. Rhie , S. Han , K. Shin and 5 Oxon, United Kingdom M. Johnson 1. Spin Convergence Research Center, Korea Institute of Science & Technology, Seoul, Republic of Korea; 2. Department of Disply and Semiconductor Physics, Korea 10:54 University, Sejong, Republic of Korea; 3. Nano Photonics CC-11. Withdrawn Research Cener, Korea Institute of Science & Technology, Seoul, Republic of Korea; 4. Department of Physics, Pohang University of Science & Technology, Pohang, Republic of Korea; 5. Naval 11:06 Research Laboratory, Washington, DC CC-12. Electronic structure and magnetic properties of

CoFe2O4/MgAl2O4 and CoFe2O4/SrTiO3 multilayers: A first- 9:42 principles study of strain and interface effects.R. Arras1 and L. Calmels11. CEMES-CNRS, Toulouse Cedex 4, France CD-05. Fabrication of a Perpendicular-MTJ-Based Compact Nonvolatile Programmable Switch Using Shared-Write- Control-Transistor Structure. D. Suzuki1,2, M. Natsui1,2, 11:18 A. Mochizuki1, S. Miura3, H. Honjo3, K. Kinoshita1, H. Sato1, 1 1,2 1,4 1,2 1,2 CC-13. CoO/Al-ZnO multilayers: interfacial magnetism and electron- S. Fukami , S. Ikeda , T. Endoh , H. Ohno and T. Hanyu 1. mediated exchange. M. Charilaou1, C. Bordel1,3 and Center for Spintronics Integrated Systems, Tohoku University, F. Hellman1,21. Physics, University of California, Berkeley, Sendai, Miyagi, Japan; 2. Research Institute of Electrical Berkeley, CA; 2. Materials Sciences Division, Lawrence Berkeley Communication, Tohoku University, Sendai, Miyagi, Japan; 3. National Laboratory, Berkeley, CA; 3. Groupe de Physique des Green Platform Research Laboratories, NEC Corporation, Matériaux, Université de Rouen, St Etienne du Rouvray, France Tsukuba, Ibaraki, Japan; 4. Graduate School for Engineering, Tohoku University, Sendai, Miyagi, Japan 96 PROGRAM PROGRAM 97

9:54 11:18 CD-06. Three-terminal magnetic tunneling junction device with CD-13. Low temperature scaling of CoFeB/MgO interface magnetic perpendicular anisotropy CoFeB sensing layer. H. Honjo1, anisotropy. A. Singh1,2, M. Arora3, S. Gupta2,4, E. Girt3, S. Fukami2, K. Ishihara3, R. Nebashi1, K. Kinoshita2, S. Okatov2, C. Sivakumar1,2 and O.N. Mryasov1,21. Physics, K. Tokutome1, M. Murahata2, S. Miura1, N. Sakimura1, University of Alabama, Tuscaloosa, AL; 2. MINT Center, T. Sugibayashi1, N. Kasai2 and H. Ohno2,41. Green Platform University of Alabama, Tuscaloosa, AL; 3. Physics, Simon Fraser Research Laboratories, NEC, Tsukuba, Japan; 2. Center for University, Burnaby, BC, Canada; 4. Metallurgical and Materials Spintronics Integrated Systems, Tohoku University, Sendai, Japan; Engineering, University of Alabama, Tuscaloosa, AL 3. Smart Energy Research Laboratories, NEC, Tsukuba, Japan; 4. Laboratory for Nanoelectronics and Spintronics, Research Institute of Electrical Communication, Tohoku University, Sendai, Japan WEDNESDAY GOVERNOR’S SQ 14 10:06 MORNING 8:30 CD-07. Mixing antiferromagnets to tune NiFe-(IRMN/FEMN) interfaces and related TA-MRAM exchange bias dispersions. K. Akmaldinov1,2, C. Ducruet2, C. Portemont2, J. Vidal2, Session CE I. Joumard1, I. Prejbeanu1, B. Dieny1 and V. Baltz11. SPINTEC, ELECTRIC AND STRAIN EFFECTS ON Grenoble, France; 2. CROCUS Technology, Grenoble, France MAGNETISM AND TRANSPORT Evgeny Tsymbal, Chair 10:18

CD-08. Vector Spin Circuit Modeling of MTJ based Spin Transfer 8:30 Devices. S. Manipatruni1, D.E. Nikonov1 and I.A. Young11. Intel Components Research, hillsboro, OR CE-01. Room-temperature reversible electrical switching of the magnetic order at the Fe/BaTiO3 interface.(Invited) G. Radaelli1, D. Petti1, P. Torelli2, B.R. Salles2, I. Fina3, 10:30 D. Gutièrrez3, E. Plekhanov4, C. Rinaldi1, M. Cantoni1, 4 3 2 1 CD-09. Analysis of Single-Event Upset in MTJ/MOS-Hybrid Circuits S. Picozzi , J. Fontcuberta , G. Panaccione and R. Bertacco 1. Employing Calculation of Switching Probability by Radiation- LNESS - Dipartimento di Fisica - Politecnico di Milano, Como, Induced Current. N. Sakimura1,2, R. Nebashi1, M. Natsui2, Italy; 2. Consiglio Nazionale delle Ricerche, CNR-IOM, T. Hanyu2, H. Ohno2 and T. Sugibayashi11. NEC Corporation, Laboratorio TASC in Area Science Park, Trieste, Italy; 3. Institut Tsukuba, Japan; 2. Tohoku University, Sendai, Japan de Ciència de Materials de Barcelona (ICMAB-CSIC), Campus UAB, Bellaterra, Spain; 4. Consiglio Nazionale delle Ricerche, CNR-SPIN, L’Aquila, Italy 10:42

CD-10. Achieving perpendicular anisotropy in half-metallic Heusler 9:06 alloys for spin device applications. K. Munira1, J. Romero2 and W.H. Butler1,21. Center for Materials for Information Technology, CE-02. Local Control of Magnetic Anisotropy in Permalloy Thin Films Coupled to Ferroelectric Domains of BaTiO Single University of Alabama, Tuscaloosa, AL; 2. Department of Physics 3 1, T. Gao1, S. Cheong2 and I. Takeuchi11. and Astronomy, University of Alabama, Tuscaloosa, AL Crystals. S.W. Fackler Materials Science & Engineering, University of Maryland, College Park, MD; 2. Physics & Astronomy, Rutgers, the State 10:54 University of New Jersey, Piscataway, NJ CD-11. Effect of magnetic parameters on switching characteristics of a synthetic antiferromagnetic structure with perpendicular 9:18 magnetic anisotropy. G. Hu1, L. Liu1 and D. Worledge11. IBM T CE-03. Dynamic Magnetoelectric Coupling in Co/PZT Bilayers. J Watson Research Center, Yorktown Heights, NY O. Vlasin1,2, R. Jarrier2, G. Herranz1 and S. Cherifi21. ICMAB- CSIC, Bellaterra, Spain; 2. IPCMS, CNRS and UdS 23, 11:06 Strasbourg, France CD-12. Three terminal logic gates based on graphene lateral spin valves. H. Wen1, Z. Lin1, W. Amamou1, T. Zhu1, Y. Luo1, J. Chen1, J. Shi1 and R.K. Kawakami11. Physics and Astronomy, University of California, Riverside, Riverside, CA 98 PROGRAM PROGRAM 99

9:30 WEDNESDAY GOVERNOR’S SQ 15 CE-04. Exchange bias study of Co/ BiFeO3 thin film heterostructures MORNING with different orientation BiFeO3 epitaxial films. T. Gao1, 8:30 S. Maruyama1, M. Murakami1, I. Takeuchi1, S.E. Lofland2, W. Ratcliff3, X. Zhang3, R. Shull3, S. Bowden3, J. Unguris3 and Session CF 3 D. Pierce 1. University of Maryland, College Park, MD; 2. MAGNETOCALORICS AND Department of Physics and Astronomy, Rowan University, Glassboro, NJ; 3. National Institute of Standards and Technology, MAGNETOELASTICS I Gaithersburg, MD Pedro Gorria, Chair

9:42 8:30 1 CE-05. Memristive tunnel junctions. (Invited) M. Bibes 1. CNRS, CF-01. Influence of Initial Particle Size Distribution on Palaiseau, France Magnetostrictive Properties of Cobalt Ferrite. C.I. Nlebedim1,2 and D.C. Jiles1,21. Ames Laboratory, US Department of Energy, 10:18 Iowa State University, AMES, IA; 2. Department of Electrical and Computer Engineering, Iowa State University, Ames, IA CE-06. Shapeable magnetoelectronics. (Invited) D. Makarov11. IFW Dresden, Dresden, Germany 8:42

10:54 CF-02. Investigation of the Interaction of Magnetic Field with the Auxetic behavior of Galfenol. G. Raghunath1 and A.B. Flatau11. CE-07. First-principles study of the piezomagnetic effect in Department of Aerospace Engineering, University of Maryland, 1,2 transition-metal fluorides MF2 (M = Mn, Fe, Co). S. Mu and College Park, MD K.D. Belashchenko1,21. Department of Physics and Astronomy, University of Nebraska-Lincoln, Lincoln, NE; 2. Nebraska Center 8:54 for Materials and Nanoscience, University of Nebraska-Lincoln, Lincoln, NE CF-03. Magnetic Force Microscopy and Brillouin Light Scattering

study of magnetostrictive Fe0.8Ga0.2 film with stripe domains. 1 2 3,4 1 3 11:06 S. Tacchi , S. Fin , G. Carlotti , G. Gubbiotti , M. Madami , M. Marangolo5, M. Eddrief5, D. Bisero2, A. Rettori6,4 and CE-08. Electric field control of spin polarization in spin filter tunnel M. Pini71. Istituto Officina dei Materiali (IOM)-CNR, Perugia, junctions. A. Pal1, K. Senapati2, Z.H. Barber1 and Italy; 2. CNISM and Dipartimento di Fisica, Università di M.G. Blamire11. Department of Materials Science and Ferrara,, Ferrara, Italy; 3. Dipartimento di Fisica, Università di Metallurgy, University of Cambridge, Cambridge, Perugia, Perugia, Italy; 4. Centro S3, c/o Istituto Nanoscienze - Cambridgeshire, United Kingdom; 2. School of physical sciences, CNR, Modena, Italy; 5. Institut des NanoSciences de Paris, National institute of Science Education and Research, UPMC-CNRS UMR, Paris, France; 6. Dipartimento di Fisica, Bhubaneswar, Orissa, India Università di Firenze, Sesto Fiorentino- Firenze, Italy; 7. Istituto dei Sistemi Complessi (ISC)- CNR, Sesto Fiorentino- Firenze, Italy 11:18 CE-09. Electrical and magnetic properties of magnetoelectric 1 1 1 1 9:06 material Cr2O3 T. Ashida , M. Oida , N. Shimomura , T. Nozaki and M. Sahashi11. Electric Engineering, Tohoku university, CF-04. Magnetic properties of epitaxial Fex Ga1-x thin films. Sendai, Miyagi, Japan S.R. Bowe1,2, D.E. Parkes1, R.P. Beardsley1, M. Wang1, P. Wadley1, V. Holý3, L.R. Shelford2, S.A. Cavill2 and A.W. Rushforth11. Physics and Astronomy, University of Nottingham, Nottingham, Nottinghamshire, United Kingdom; 2. I06, Diamond Light Source, Oxford, Oxfordshire, United Kingdom; 3. Faculty of Mathematics and Physics, Charles University, Prague, Prague, Czech Republic

9:18 CF-05. Measurement of magnetostriction in an individual multilayered Fe-Ga/Cu nanowire using atomic force microscopy. J. Park1, E.C. Estrine2, B.J. Stadler2 and A.B. Flatau11. Aerospace engineering, University of Maryland, College Park, MD; 2. Electrical Engineering, University of Minnesota, Minneapolis, MN 100 PROGRAM PROGRAM 101

9:30 10:42 CF-06. The influence of induced crystallographic texture on magnetic CF-12. Zero volume change first-order phase transition in Fe2P- properties and magnetostriction of Fe-Ga microwires. based magnetocaloric compounds. L. Caron1, H. Nguyen2,1, N. Lupu1, M. Lostun1, I. Murgulescu1, G. Ababei1, L. Budeanu1 Z. Ou1 and E. Brück11. Delft University of Technology, Delft, and H. Chiriac11. Magnetic Materials and Devices, National Netherlands; 2. Institut Neel, Grenoble, France Institute of R&D for Technical Physics, Iasi, Romania 10:54 9:42 CF-13. Spin-reoriented stabilization in a Ni51Mn33.4IN15.6 Heusler CF-07. Temperature dependence of abnormal grain growth and high alloy. M. Ghahremani1, H. ElBidweihy1, H.M. Seyoum2, magnetostriction in Goss-oriented Fe-Al thin sheets. S. Na1 and M. Ovichi1, L.H. Bennett1 and E. Della Torre11. Electrical and A.B. Flatau11. Aerospace Engineering, University of Maryland, Computer Engineering, The George Washington University, College Park, MD Washington, DC; 2. University of the District of Columbia, Washington, DC 9:54 11:06 CF-08. NiMnGa thin films and nano-disks: a multiscale investigation. F. Albertini1, P. Ranzieri1, S. Fabbrici2,1, V. Chiesi1, CF-14. Generalized Magnetocaloric Properties of Ni-Mn-In And Ni- M. Campanini1, F. Casoli1, L. Nasi1, L. Righi3,1, F. Celegato4, Mn-In-Co Heusler Alloys. T. Gottschall1, K. Skokov1, J. Liu2 G. Barrera4 and P. Tiberto4,11. IMEM-CNR, Parma, Italy; 2. MIST and O. Gutfleisch1,31. TU Darmstadt, Darmstadt, Germany; 2. E-R Lab., Bologna, Italy; 3. Chemistry Department, Parma NIMTE, Ningbo, China; 3. IWKS Group Materials Recycling and University, Parma, Italy; 4. INRIM, Torino, Italy Resource Strategy, Fraunhofer ISC, Hanau, Germany

10:06 11:18 CF-09. Electric-field control of the magnetic configuration of Ni CF-15. Structure, magnetic and magnetocaloric properties of nanostructures fabricated on pre-poled PMN-PT (011) La0.85K0.15MnO3 compound produced by a reactive Spark mediated by strain. S. Finizio1, M. Foerster1,2, M. Buzzi3, Plasma Sintering route. Y. Regaieg1,2, S. Ammar1, L. Sicard1, C. Vaz1,4, J. Hockel5, T. Miyawaki6, C. Mix1, M. Mawass1,7, M. Koubaa2 and A. Cheikhrouhou21. Chemistry, University of A. Tkach1, S. Valencia8, F. Kronast8, F. Nolting8, G. Carman8 and Paris Diderot, Paris, France; 2. Physics, University of Sfax, Sfax, M. Kläui11. Institut für Physik, Johannes Gutenberg Universität, Tunisia Mainz, Germany; 2. ALBA Synchrotron Light Source, Cerdanyola del Valles, Spain; 3. Swiss Light Source, Paul Scherrer Institut, Villigen, Switzerland; 4. SwissFEL, Paul Scherrer Institut, Villigen, Switzerland; 5. Department of Mechanical and Aerospace Engineering, University of California, Los Angeles, WEDNESDAY GOVERNOR’S SQ 16 CA; 6. Department of Crystalline Materials Science, Nagoya MORNING University, Nagoya, Japan; 7. Max-Planck-Institut für Intelligente Systeme, Stuttgart, Germany; 8. Helmholtz Zentrum für 8:30 Materialien und Energie GmbH, Berlin, Germany Session CG

10:18 SOFT MAGNETS: AMORPHOUS AND NANOCOMPOSITE II CF-10. Magnetic Properties and Magnetocaloric Effect of NdMn2- 1,2 1,3 1 Victorino Franco, Chair xCuxSi2 Compounds. M. Md Din , J. Wang , R. Zeng , S. Kennedy3, M. Avdeev3, S. Campbell4 and S. Dou11. Institute of Superconducting and Electronic Material, University of 8:30 Wollongong, Wollongong, NSW, Australia; 2. Department of Electrical & Electronic Engineering, National Defence University CG-01. Magnetization reversal in soft magnetic amorphous of Malaysia, 5700 Sungai Besi, Kuala Lumpur, Malaysia; 3. FeSiB/CoSiB bilayer ribbons at elevated temperatures. 1 1 1 1 2 Bragg Institute,, Australian Nuclear Science and Technology I. Skorvanek , M. Capik , J. Marcin , J. Kovac , P. Svec jr. , 2 2 2 Organization, Lucas Heights, NSW, Australia; 4. School of I. Matko , D. Janickovic and P. Svec 1. Magnetism, Institute of Physical, Environmental and Mathematical Sciences, The Experimental Physics Slov. Acad. Sci., Kosice, Slovakia; 2. University of New South Wales, Canberra, ACT, Australia Institute of Physics Slov. Acad. Sci., Bratislava, Slovakia

10:30 CF-11. Control of the magneto-elastic phase transition in MnFe(P,Si,B) magnetocaloric materials.E. Brueck1 and F. Guillou11. FAME, Delft University, Delft, Netherlands 102 PROGRAM PROGRAM 103

8:42 9:54 CG-02. Effect of Si on the field-induced magnetic anisotropy in Fe- CG-08. Large current-induced GMI enhancement and domain rich nanocrystalline soft magnetic materials. R.R. Parsons1, transform of melt-extracted T. Yanai2, H. Kishimoto3, A. Kato3 and K. Suzuki11. Department Co68.15Fe4.35Si12.25B11.25Nb2Cu2 microwires by cryogenic of Materials Engineering, Monash University, Clayton, VIC, Joule annealing. D. Chen1, F. Qin2, D. Xing1, J. Liu1, H. Shen1, Australia; 2. Graduate School of Engineering, Nagasaki H. Wang1 and J. Sun11. Harbin Institute of Technology, Harbin, University, Nagasaki, 852-8521, Japan; 3. Toyota Motor Heilongjiang, China; 2. National Institute for Material Science, Corporation, Shizuoka, 410-1193, Japan Tsukuba, Ibaraki, Japan

8:54 10:06 CG-03. Field Induced Anisotropy in FeCo-based Nanocomposite CG-09. Optimization of the GMI effect of Finemet-type microwires Alloys with Reduced Early Transition Metal Content.S. Shen1, through the nanocrystallization.A. Talaat1, V. Zhukova1, P.R. Ohodnicki2, S.J. Kernion1, V. Keylin3, J.F. Huth3 and M. Ipatov1, J.M. Blanco2, M. Churyukanova3, S.D. Kaloshkin3, M.E. McHenry11. Department of Materials Science and L. Gonzalez-Legarreta4, E. Shuvaeva3, E. Zamiatkina3, Engineering, Carnegie Mellon University, Pittsburgh, PA; 2. B. Hernando4, J.J. del Val1, J. Gonzalez1 and A.P. Zhukov1,51. Chemistry and Surface Science Division, National Energy Phys. Mater., UPV/EHU, San Sebastián, Spain; 2. Dpto de Fisica Technology Laboratory (NETL), Pittsburgh, PA; 3. Magnetics, A Aplicada, EUPDS, San Sebastian, Spain; 3. Centre of composite Division of Spang and Co., Pittsburgh, PA materials, National University of Science and Technology «MISIS», Moscow, Russian Federation; 4. Dpto de Física,, Universidad de Oviedo, Oviedo, Spain; 5. IKERBASQUE, Basque 9:06 Foundation for Science, Bilbao, Spain CG-04. Eddy currents in soft magnetic Co-rich nanocomposite 1 1 ribbons with transverse domains. A. Leary , P. Xu , 10:18 M. Moneck1, P. Ohodnicki2 and M.E. McHenry11. Carnegie Mellon University, Pittsburgh, PA; 2. Division of Chemistry and CG-10. High-Energy Mechanical Milling-induced Crystallization in Surface Science, National Energy Technology Laboratory, Fe32Ni52Zr3B13. Y. Geng1, T. Ablekim2, M. Weber2, K.G. Lynn2 Pittsburgh, PA and J.E. Shield11. Mechanical & Material Engineering, University of Nebraska Lincoln, Lincoln, NE; 2. Center for Materials Research, Washington State University, Pullman, WA 9:18

CG-05. Influence of microstructure on soft magnetic properties of low 10:30 coreloss and high Bs Fe85Si2B8P4Cu1 nanocrystalline alloy. P. Sharma1, X. Zhang2, Y. Zhang1,2 and A. Makino1,21. Research CG-11. Magnetic properties and domain wall propagation in FeNiSiB and Development Center for Ultra High Efficiency Nano- glass-coated microwires. V. Zhukova1, J.M. Blanco2, M. Ipatov1 crystalline Soft Magnetic Materials, Institute for Materials and A.P. Zhukov1,31. Phys. Mater., UPV/EHU, San Sebastián, Research,, Tohoku University, Sendai, Miyagi, Japan; 2. Institute Spain; 2. Dpto. de Física Aplicada, EUPDS, UPV/EHU,, San for Materials Research, Tohoku University, Sendai, Miyagi, Japan Sebastian, Spain; 3. IKERBASQUE, Basque Foundation for Science, Bilbao, Spain 9:30 10:42 CG-06. Electro-Infiltrated Nanocomposite Soft Magnetic Cores for 1 2 2 High Frequency Applications. X. Wen , J. Starr , J.S. Andrew CG-12. Magnetic properties of amorphous Co62Nb6Zr2B30 obtained by and D.P. Arnold11. Electrical and Computer Engineering, mechanical alloying.L.M. Moreno1, J.S. Blazquez1, J.J. Ipus1, University of Florida, Gainesville, FL; 2. Materials Science and J.M. Borrego1, V. Franco1 and A. Conde11. Universidad de Engineering, University of Florida, Gainesville, FL Sevilla, Seville, Spain

9:42 10:54

CG-07. Magnetoimpedance studies on laser-annealed Fe66Ni7Si7B20 CG-13. Effects of metalloids on the magnetic properties of FeNi-based ribbons. G. Kotagiri1, V. Chunchu1, C.V. Tomy2 and amorphous alloys. A. Wang1, C. Chang1, H. Men1, B. Shen2 and G. Markandeyulu11. Physics, Indian Institute of Technology, R. Li11. Key Laboratory of Magnetic Materials and Devices, Chennai, Tamil Nadu, India; 2. Physics, Indian Institute of Ningbo Institute of Materials Technology & Engineering, Chinese Technology Bombay, Mumbai, Maharashtra, India Academy of Sciences, Ningbo, Zhejiang, China; 2. School of Materials Science and Engineering, Southeast University, Nanjing, Jiangsu, China 104 PROGRAM PROGRAM 105

11:06 9:06 CG-14. Soft magnetic Fe-based metallic glasses with high CH-04. 1/f magnetic noise in MgO/CoFeB based sensors with voltage thermoplastic formability. W. Zhang1,2, C. Fang1, Y. Li1 and controlled perpendicular anisotropy. P. Wisniowski1, X. Jia11. School of Materials Science and Engineering, Dalian M. Dabek1, T. Stobiecki1, S. Cardoso2 and P.P. Freitas21. University of Technology, Dalian, China; 2. Institute for Materials Electronics, AGH-UST, Krakow, Poland; 2. INESC-MN and IN- Research, Tohoku University, Sendai, Japan Institute of Nanoscience and Nanotechnology, Lisbon, Portugal

11:18 9:18 CG-15. Spin precession by pulsed inductive magnetometry in thin CH-05. Self-Biased 215MHz Magnetoelectric NEMS Resonator for amorphous plates.A. Caprile1,2, A. Magni1, O. Bottauscio1, Ultra-Sensitive DC Magnetic Field Detection. T. Nan1*, E. Ferrara1 and F. Fiorillo11. INRiM, Torino, Italy; 2. Politecnico Y. Hui1, M. Rinaldi1 and N. Sun11. ECE, Northeastern University, di Torino, Torino, Italy Boston, MA

9:30 CH-06. Thermal Noise in High-Performance Magnetic WEDNESDAY GOVERNOR’S SQ 12 Sensors.R. Skomski1, X. Yin1, P. Manchanda1, S. Liou1 and MORNING D.J. Sellmyer11. Department of Physics and Astronomy and 8:30 Nebraska Center for Materials and Nanoscience, University of Nebraska, Lincoln, NE Session CH MAGNETIC SENSORS 9:42 Olga Kazakova, Chair CH-07. Moore-Penrose Pesudoinverse of the Gradient Tensor in Euler’s Equation for Locating a Magnetic Dipole. T. Nara1, W. Ito2 and S. Ando11. Graduate School of Information Science 8:30 and Technology, The University of Tokyo, Tokyo, Japan; 2. CH-01. A sensor measuring the discrete Fourier coefficients of the Graduate School of Informatics and Engineering, The University leakage magnetic flux for non-destructive inspection of a pipe. of Electro-Communications, Chofu, Toko, Japan T. Nara1, M. Fujieda2 and Y. Goto31. Graduate School of Information Science and Technology, The University of Tokyo, 9:54 Hongo, Bunkyo, Tokyo, Japan; 2. The University of Electro- Communications, Chofu, Tokyo, Japan; 3. Oita University, Oita, CH-08. Field detectivity in MgO-based magnetic tunnel junction Oita, Japan sensor arrays for Non-destructive testing applications. D. Guo1,3, F. Cardoso1, R. Ferreira2, E. Paz2, S. Freitas1 and P. Freitas1,21. INESC-MN and IN-Institute of Nanoscience and 8:42 Nanotechnology, Lisbon, Portugal; 2. International Iberian CH-02. Thin Palladium-Cobalt film as a hydrogen sensor. M. Kostylev1 Nanotechnology Laboratory (INL), Braga, Portugal; 3. Key and C.S. Chang11. School of Physics, The University of Western Laboratory for Magnetism and Magnetic Materials of the Australia, Crawley, WA, Australia Ministry of Education, Lanzhou University, Lanzhou, China

8:54 10:06 CH-03. Magnetic field sensor with voltage tunable sensing properties. CH-09. A Comparative Study of Probe Designs for Detection of 1 W. Skowronski1, P. Wisniowski1, T. Stobiecki1, S. Cardoso2, Magnetic Barkhausen Emissions. N. Prabhu Gaunkar , 1 1,2 1,2 P.P. Freitas2, G. Reiss3 and S. van Dijken41. Department of O. Kypris , C.I. Nlebedim and D.C. Jiles 1. Department of Electronics, AGH University of Science and Technology, Krakow, Electrical and Computer Engineering, Iowa State University, Poland; 2. INESC-MN and IN- Institute of Nanoscience and Ames, IA; 2. Ames Laboratory, US Department of Energy, Iowa Nanotechnology, Lisbon, Portugal; 3. Thin Films and Physics of State University, Ames, IA Nanostructures, Bielefeld University, Bielefeld, Germany; 4. Department of Applied Physics, Aalto University School of 10:18 Science, Espoo, Finland CH-10. Adjusting free layer structures of magnetic tunnel junctions for high sensitive magnetoresistive sensors. X. Yin1, R. Skomski1, D.J. Sellmyer1, S. Liou1, S.E. Russek2, E. Evards2, J. Moreland2, A.S. Edelstein3, L. Yuan4, M. Yan4 and J. Shen41. Physics, University of Nebraska- Lincoln, Lincoln, NE; 2. National Institute of Standards and Technology, Boulder, CO; 3. U.S. Army Research Laboratory, Adelphi, MD; 4. Western Digital Corporation, Fremont, CA 106 PROGRAM PROGRAM 107

10:30 CP-03. Theory of magnetization dynamics in a dual-free-layer spin- torque nano-oscillator with counter-precessing magnetic CH-11. Enhancement of giant magnetoresistance by L2 ordering in 1 2 2 1 moments. O. Prokopenko , V. Tiberkevich and A. Slavin 1. Co Fe(Ge Ga ) Heusler alloy current-perpendicular-to- 2 0.5 0.5 Faculty of Radiophysics, Taras Shevchenko National University of plane pseudo spin valves. S. Li1, Y. Takahashi1, T. Furubayashi1 1 Kyiv, Kyiv, Ukraine; 2. Department of Physics, Oakland and K. Hono 1. National Institute for Materials Science, Tsukuba, University, Rochester, MI Japan

CP-04. Phase locking of magnetic vortex oscillators. Y. Zhou1, 10:42 F. Sanches2, V. Tyberkevych2 and A. Slavin21. Physics, University CH-12. Direct detection of magnetic fields in the 100 pT range at low of Hong Kong, Hong Kong, Hong Kong; 2. Physics, Oakland frequency using large arrays of large area MTJs. E. Paz1, University, Rochester, MI S. Serrano-Guisan1, R. Ferreira1 and P.P. Freitas11. Spintronics, INL-International Iberian Nanotechnology Laboratory, Braga, CP-05. Validity of the macromagnetic model in spin-transfer Portugal switching: activation volume and delay.S. Yamashita1, S. Miwa1, M. Fukumoto1, H. Tomita1, T. Nagase2, K. Nishiyama2, 2 2 2 2 10:54 E. Kitagawa , M. Yoshikawa , T. Daibou , M. Nagamine , T. Kishi2, S. Ikegawa2, N. Shimomura2, H. Yoda2 and Y. Suzuki11. CH-13. Magnetic tunnel junction based eddy current testing probe for Graduate School of Engineering Science, Osaka University, 1 2,3 detection of surface defects. F.A. Cardoso , L. Rosado , Toyonaka, Osaka, Japan; 2. Corporate Research & Development 5 5 1 2,4 3 R. Ferreira , E. Paz , S. Cardoso , P.M. Ramos , M.S. Piedade Center, Toshiba Corporation, Kawasaki, Kanagawa, Japan and P.P. Freitas1,51. INESC-MN, Lisboa, Portugal; 2. Instituto Superior Técnico, Lisboa, Portugal; 3. INESC-ID, Lisboa, Portugal; 4. Instituto de Telecomunicações, Lisboa, Portugal; 5. CP-06. Spin torque ferromagnetic resonance in CoFe/Pt and 1 2 International Iberian Nanotechnology Laboratory, Lisboa, CoFeB/Pt bilayer films. A. Ganguly , K. Kondou , 3 3 2,3 4 2,4 Portugal H. Sukegawa , S. Mitani , S. Kasai , Y. Niimi , Y. Otani and A. Barman11. Department of Condensed Matter Physics and Material Sciences, S N Bose National Centre For Basic Sciences, Kolkata, West Bengal, India; 2. RIKEN-CEMS, Wako, Japan; 3. National Institute for Materials Science, Tsukuba, Japan; 4. WEDNESDAY EXHIBIT HALL Institute for Solid State Physics, University of Tokyo, Kashiwa, Japan MORNING 9:30 CP-07. Spin Torque Oscillation of Synthetic Antiferromagnetic Free Layer in Dual Magnetic Tunnel Junction. X. Chao1, Y. Zhang1, Session CP H. Zhao1 and J. Wang11. Department of Electrical and Computer SPIN TRANSFER AND SPIN HALL EFFECTS Engineering, University of Minnesota, Minneapolis, MN (Poster Session)

Yasuhiro Niimi, Chair CP-08. Direct measurement of spin polarization across C60 tunnel junctions.F. Al Ma’Mari1, M. Wheeler1, T. Moorsom1, B.J. Hickey1 and O. Cespedes11. University of Leeds, Leeds, CP-01. Stochastic resonance in CoFeSiB magnetic tunnel junctions United Kingdom with low magnetic anisotropy. M. Umeyama1, S. Miwa1, H. Kubota2, R. Matsumoto2, K. Yakushiji2, A. Fukushima2, S. Yuasa2, N. Mizuochi1, T. Shinjo1 and Y. Suzuki11. Graduate CP-09. Non-reciprocal Oersted field contribution to the current- School of Engineering Science, Osaka University, Toyonaka, induced frequency shift of magnetostatic surface spin Osaka, Japan; 2. Spintronics Research Center, National Institute waves.M. Haidar1, M. Bailleul1, Y. Lao3,2 and M. Kostylev21. of Advanced Industrial Science and Technology (AIST), Tsukuba, Institut de Physique et Chimie des Matériaux de Strasbourg - Ibaraki, Japan IPCMS, UMR 7504 CNRS, Université de Strasbourg, Strasbourg, France; 2. School of Physics, The University of Western Australia, Crawley, WA, Australia; 3. University of Science and Technology CP-02. Magnetic field annihilation of magnetic droplet solitons in of China, Hefei, China nano-contact spin-torque oscillators. S. Chung1,3, S.M. Mohseni1,2, S.R. Sani1,2, A. Eklund4, E. Iacocca3 and J. Åkerman1,31. Materials Physics, School of ICT, Royal Institute CP-10. Understanding the Spectroscopic FMR Signature of the of Technology, Electrum 229, 164 40 Kista, Sweden; 2. NanOsc Anomalous Write Error Rate Tail in MTJ MRAM. AB, Electrum 205, 164 40 Kista, Sweden; 3. Department of E.R. Evarts1, W.H. Rippard1 and M.R. Pufall11. Magnetics Group, Physics, University of Gothenburg, 412 96 Gothenburg, Sweden; National Institute of Standards and Technology, Boulder, CO 4. Devices and Circuits, School of ICT, Royal Institute of Technology, Electrum 229, 164 40 Kista, Sweden 108 PROGRAM PROGRAM 109

CP-11. Mechanical effects induced by ferromagnetic resonance in WEDNESDAY EXHIBIT HALL magnetic multilayers deposited on cantilevers. S. Lim1, 1 1 2 1 MORNING T. Wallis , A. Imtiaz , A. Slavin and P. Kabos 1. 9:30 Electromagnetics Division, NIST, Boulder, CO; 2. Physics, Oakland University, Rochester, MI Session CQ

CP-12. Estimation of the amplitude-phase coupling parameter from CRITICAL PHENOMENA AND ELECTRONIC the linewidth on spin transfer oscillators: Normalized STRUCTURE temperature method.F. Garcia-Sanchez1, J.F. Sierra1, (Poster Session) M. Quinsat2, D. Gusakova1, L.D. Prejbeanu1, B. Dieny1 and U. Ebels11. SPINTEC, CEA/CNRS/UJF/Grenoble INP, Grenoble, Christy Kinane, Co-Chair France; 2. CEA-LETI, Grenoble, France Jason Morgan, Co-Chair

CP-13. Current-induced synchronized switching of CQ-01. Exchange interaction in hexagonal MnRhP from first- 1 1 2 3 magnetization.S. Seo1, J. Moon1 and K. Lee1,21. Dept of Mater. principles studies. X. Liu , Q. Zhang , M. Yue , Z. Altounian and 1 Sci. & Eng., Korea University, Seoul, Republic of Korea; 2. KU- P. Liu 1. Physics, University of Texas at Arlington, Arlington, TX; KIST Graduate School of Converging Science and Technology, 2. Material Science and Engineering, Bejing University of Korea University, Seoul, Republic of Korea Technology, Beijing, China; 3. physics department, McGill University, Montreal, QC, Canada

CP-14. Wire geometry for spin Hall effect switching of nanomagnets. D. Nikonov1, S. Manipatruni1 and I. Young11. Intel Components CQ-02. Electronic and magnetic properties of double perovskite 1 Research, hillsboro, OR Dy2MnCoO6 by first-principles calculation.C. Ganeshraj and P.N. Santhosh11. Physics, IIT Madras, Chennai, Tamilnadu, India

CP-15. Threshold current for switching of a perpendicular magnetic layer induced by spin Hall effect. K. Lee1,2, S. Lee1, B. Min2 and CQ-03. Effect of stacking faults on the magnetocrystalline anisotropy 1 2 K. Lee1,31. Department of Materials Science and Engineering, of hcp Co: a first-principles study.C.J. Aas , L. Szunyogh , 1 1 Korea University, Seoul 136-701, Republic of Korea; 2. Spin R.F. Evans and R.W. Chantrell 1. Department of Physics, Convergence Research Center, Korea Institute of Science and University Of York, York, England, United Kingdom; 2. Technology, Seoul 136-791, Republic of Korea; 3. KU-KIST Theoretical Physics and Condensed Matter Research Group of Graduate School of Converging Science and Technology, Korea Hungarian Academy of Sciences, Budapest University of University, Seoul 136-713, Republic of Korea Technology and Economics, Budapest, Hungary

CP-16. Enhanced Magneto-Thermoelectric Effect in CoFeB/Ta Film. CQ-04. Rational design of Dirac points in TM doped Mg-Al 1 1 1 2 1 D. Kim1, K. Lee1, B. Park1, J. Jeong2, K. Lee3, H. Song4, J. Sohn4 spinel.Y. Lu , B. Shao , Y. Zhang , M. Feng and X. Zuo 1. and S. Shin4,51. Department of Materials Science and College of Information Technical Science, Nankai University, Engineering, KI for the Nanocentury, KAIST, Daejeon, Republic Tianjin, China; 2. School of Physics, Nankai University, Tianjin, of Korea; 2. Department of Materials Science and Engineering, China Graduate School of Green Energy Technology, Chungnam National University, Daejeon, Republic of Korea; 3. School of CQ-05. New approach to spin-resolved photoemission using hard X- Mechanical and Advanced Materials Engineering, UNIST, Ulsan, rays: Electronic and magnetic states of an FeNi alloy film Republic of Korea; 4. Department of Physics and CNSM, KAIST, buried under a Au thin film. S. Ueda1, M. Mizuguchi2, Daejeon, Republic of Korea; 5. Department of Emerging T. Kojima2, S. Ishimaru1, M. Tsujikawa3, M. Shirai3,4, Materials Science, DGIST, Daegu, Republic of Korea K. Takanashi2 and O. Sakata11. National Institute for Materials Science, Hyogo, Japan; 2. IMR, Tohoku University, Sendai, Japan; 3. CSIS, Tohoku University, Sendai, Japan; 4. RIEC, Tohoku University, Sendai, Japan

CQ-06. Magnetic Orders of LaTiO3 Under Epitaxial Strain: A first- principles study.Y. Weng1, X. Huang1, Y. Tang1 and S. Dong11. Southeast University, Nanjing, China

CQ-07. High pressure inducing magnetic ordering change in Eu1- xYbxGa4 compounds. R.D. dos Reis1,2, L.S. Veiga1,2, N. Souza- Neto1 and F.G. Gandra21. Braziilian Synchroton Light Laboratory, Campinas, São Paulo, Brazil; 2. State University of Campinas, Campinas, São Paulo, Brazil 110 PROGRAM PROGRAM 111

CQ-08. The effect of rare-earth substitution on the magnetic and CQ-16. Spin Reorientation effect on Phonon Raman Scattering in thermoelectric properties of Bi tellurides: first-principles NdFeO3 Single Crystal. M.K. Singh1, G. Singh1 and calculations.T.V. Quang1 and M. Kim21. Dept of Physics, Ajou R.S. Katiyar21. Material Science, University of Allahabad, University, Suwon, Republic of Korea; 2. Dept of Nano Physics, Allahabad, India; 2. Department of Physics and Institute of Sookmyung Womens’s University, Seoul, Republic of Korea Functional Nano Materials, University of Puerto Rico, San Juan, Puerto Rico

CQ-09. Magnetic and nuclear structure of the intermetallic Eu3Ir4Sn13 compound studied by neutron diffraction.J.R. Mardegan1,5, N. Aliouane2, L.N. Coelho3, O. Aguero4, E.M. Bittar4, J.C. Lang5, P.G. Pagliuso1, I.L. Torriani1 and C. Giles1,51. Instituto de Física ‘Gleb Wataghin’, Universidade Estadual de Campinas, WEDNESDAY EXHIBIT HALL Campinas, Sao Paulo, Brazil; 2. Laboratory for Neutron MORNING Scattering, Paul Scherrer Institute, Villigen, Switzerland; 3. 9:30 Instituto de Fisica, Universidade de Brasilia, Brasilia, DF, Brazil; 4. Laboratorio Nacional de Luz Síncrotron, Campinas, Sao Paulo, Session CR Brazil; 5. Advanced Photon Source, Argonne National Laboratory, Argonne, IL WIRELESS AND SOFT MAGNET APPLICATIONS

CQ-10. Putative quantum criticality in the (Cr90Ir10)100-yVy alloy (Poster Session) system. P.R. Fernando1, A. Prinsloo1, C.J. Sheppard1 and Yajie Chen, Chair L.A. Lodya21. Physics, University of Johannesburg, Auckland Park, 2006, South Africa; 2. Research & Development, Materials Science, Sasol Technology, Sasolburg, 1947, South Africa CR-01. GHz Integrated Magnetic Inductors with FeGaB/Al2O3 Multilayer Films for Significant Inductance and Quality Factor Enhancement. Y. Gao1, S. Zare1, X. Yang1, T. Nan1, CQ-11. Magnetism of perovskite cobaltites with Kramers rare-earth Z. Zhou1, M. Onabajo1 and N. Sun11. Electrical and Computer 1 2 1 1 ions. Z. Jirak , H. Fujishiro , J. Hejtmanek , K. Knizek , Engineering, Northeastern University, Boston, MA P. Novak1 and E. Santava11. Institute of Physics ASCR, Prague, Czech Republic; 2. Faculty of Engineering, Iwate University, Morioka, Japan CR-02. Design of Compact and High Efficiency Core Shape for High Frequency Transformer of Module-Integrated Inverter. J. Yoo1 and T. Jung11. Electrical engineering, Kyungnam university, CQ-12. Influence of magnetic field on the Néel temperature of the Chang-won, Republic of Korea 1 1 (Cr84Re16)89.6V10.4 alloy. B.S. Jacobs , C.J. Sheppard and A.R. Prinsloo11. Physics, University OF Johannesburg, Johannesburg, Gauteng, South Africa CR-03. Performance of FeCoB based thin-film microwave noise suppressor applied to the EMI design in the GHz frequency range. J. Qiu1, J. Yang1 and W. Li21. Sensors and Instruments CQ-13. A comparison study on magnetic behaviors in TbNi2, TbMn2 Research Center, College of Optoelectronic Engineering, 1,2 1 and TbNi2Mn compounds. J. Wang , M.F. Md Din , Chongqing University, Chongqing, Chongqing, China; 2. College 2 3 2 4 1 S.J. Kennedy , S.J. Campbell , A.J. Studer , G. Wu and S. Dou 1. of Engineering, University of California, Davis, Davis, CA Institute for Superconducting & Electronic Materials, University of Wollongong, Wollongong, NSW, Australia; 2. Bragg Institute,, ANSTO, Sydney, NSW, Australia; 3. School of Physical, CR-04. Measurements on real and imaginary part of transverse 1 1 Environmental and Mathematical Sciences, The University of New susceptibility of particulate system. I. Dumitru , D. Cimpoesu 1 South Wales, Canberra, Sydney, ACT, Australia; 4. Institute of and A. Stancu 1. Faculty of Physics, Alexandru Ioan Cuza Physics, Chinese Academy of Science, Beijing, China University, Iasi, Iasi, Romania

CQ-14. Magnetic Phase Diagram of the Diluted Easy Axis Low CR-05. Study of Resonant Self-Charging Rats Experiment 1,2 1 Anisotropic Antiferromagnet Cs Fe In . 2H O. R.S. Freitas1, Playground Based on Witricity Technology. J. Wang , K. Liu , 2 (1-x) x 2 1 2 A. Paduan-Filho1 and C.C. Becerra11. Departamento de Física J. Ruan and M. Sun 1. School of Electrical Engineering, Wuhan dos Materiais e Mecânica, Instituto de Física, Universidade de University, Wuhan, Hubei, China; 2. Neurological Surgery, São Paulo, São Paulo, SP, Brazil University of Pittsburgh, Pittsburgh, PA

CQ-15. Evolution of Griffiths Phase in La Bi Mn Ti O CR-06. Transfer Efficiency Analysis of Magnetic Resonance Wireless 0.4 0.6 (1-x) x (3+δ) 1 Perovskite Oxide. V. Dayal1, P.V. Kumar1, R.L. Hadimani2 and Power Transfer With Intermediate Resonant Coil. Q.Z. Li and 1 D.C. Jiles21. Department of Physics, Maharaja Institute of S. Huang 1. College of electrical and information engineering, Technology-Mysore, Mandya, Karnataka, India; 2. Department of Changsha, China Electrical and Computer Engineering, Iowa State University, Ames IA, IA 112 PROGRAM PROGRAM 113

CR-07. Quantitative comparison of wirelessly dynamic power CR-15. A Integrated Design of Microspeaker Module with Smaller transfer techniques for electric vehicles. W. Li 1, K. Chau1 and Volume. D. Xu1, P. Sun2, J. Kwon3 and S. Hwang11. School of C. Liu11. The University of Hong Kong, Hong Kong, Hong Kong Mechanical Engineering, Pusan National University, Busan, Busan City, Republic of Korea; 2. Research and Development Center, SMDERI, Shanghai, Shanghai, China; 3. Research and CR-08. An Efficient Wireless Power Transfer System Using Chaotic Development Center, EM-Tech, Anyang, Gyeonggi-do, Republic of Excitations for Electric Vehicle Applications. Z. Zhang1, Korea K.T. Chau1, C. Liu1, C. Qiu1 and F. Lin11. Dept. of Electrical and Electronic Engineering, The University of Hong Kong, Hong Kong, Hong Kong CR-16. Voltage Tunable Magnetoelectric Thin Film Inductor. M. Mohebbi1, K. Ebnabbasi1 and C. Vittoria11. Northeastern University, Boston, MA CR-09. Quantitative Comparison of Dynamic Flux Distribution of Magnetic Couplers for Roadway Electric Vehicle Wireless Charging System. C. Qiu1, K. Chau1 and C. Liu11. The University of Hong Kong, Hong Kong, Hong Kong WEDNESDAY EXHIBIT HALL CR-10. A study on stabilization of output voltage for stationary MORNING contactless electric vehicle charging. T. Takura1, F. Sato1 and H. Matsuki21. Graduate school of engineering, Tohoku University, 9:30 Sendai, Japan; 2. Graduate school of biomedical engineering, Tohoku University, Sendai, Japan Session CS SUPERCONDUCTIVITY AND COMPLEX CR-11. A study of leakage magnetic field from twisted coil for OXIDES movable electric vehicle charging via electromagnetic (Poster Session) induction. T. Fushimi1, T. Takura1, F. Sato1, T. Sato2 and H. Matsuki21. Graduate School of Engineering, Tohoku univ., Stuart Calder, Chair Sendai, Japan; 2. Graduate School of Biomedical Engineering, Tohoku univ., Sendai, Japan CS-01. Rashba-type spin-orbit interaction and superconductivity in bulk crystals. G. Eguchi1,2, H. Wadati3, T. Sugiyama4, 5 2 2 CR-12. Effect of Variation of DC Bias Conditions on Loss and Flux E. Ikenaga , S. Yonezawa and Y. Maeno 1. Engineering Science, inside Transformer Core.Z. Zhao1, Z. Cheng2, N. Takahashi3, Osaka University, Toyonaka, Osaka, Japan; 2. Graduate School B. Forghani4, F. Liu1, Y. Li1, L. Liu2 and S. Zhang11. Province- of Science, Kyoto University, Kyoto, Kyoto, Japan; 3. Applied Ministry Joint Key Laboratory of Electromagnetic Field and Physics and Quantum-Phase Electronics Center, University of Electrical Apparatus Reliability, Hebei University of Technology, Tokyo, Tokyo, Tokyo, Japan; 4. Research Center fo Tianjin, China; 2. R & D Center, Baoding Tianwei Group Co., SynchrotronLight Applications, Kasuga, Fukuoka, Japan; 5. LTD, Baoding, Hebei, China; 3. Dept. of E.E., Okayama JASRI/ SPring-8, Kouto, Mikazuki, Hyogo, Japan University, Okayama, Japan; 4. Infolytica Corporation, Montréal, QC, Canada CS-02. Magnetic properties of the layered oxypnictides (LnO)MnAs (Ln = rare earth element). Y. Morosawa1, A. Naito1, 1 1 1 CR-13. The influence of the fifth harmonic of the grid on the T. Watanabe , Y. Takano and K. Takase 1. Nihon University, magnetostrictive deformation of a three-phase transformer Tokyo, Japan core. S. Gorji Ghalamestani1, L. Vandevelde1, J.J. Dirckx2 and 1 J.A. Melkebeek 1. Electrical Energy, Systems & Automation, CS-03. High field NMR in transition metal substituted Ghent University, Ghent, Belgium; 2. Laboratory of Biomedical 1 1 1 BaFe2As2T. Macedo Garitezi , G.G. Lesseux , P.S. Rosa , Physics, Antwerp University, Antwerp, Belgium C. Adriano1, A.P. Reyes2, P.L. Kuhns2, P.G. Pagliuso1 and R.R. Urbano11. Universidade Estadual de Campinas, Campinas, CR-14. Fe-based Composited Cores for Single-Phase Transformers SP, Brazil; 2. National High Magnetic Field Laboratory, Florida Fabricated with High Induction Amorphous Material. State University, Tallahassee, FL S. Cheng1, C. Hsu1,2 and C. Tseng31. Department of Power Mechanical Engineering, Army Academy R.O.C., Tao-Yuan, CS-04. Transport Critical Current Measurements on a Cu- Taiwan; 2. Division of Electrical Engineering, Fortune Electric 1 substituted BaFe2As2 Superconductor. T. Macedo Garitezi , Company, Ltd., Tao-Yuan, Taiwan; 3. Division of Physics, Institute P. Rosa1, C. Adriano1, T. Grant2, R.R. Urbano1, Z. Fisk2 and of Nuclear Energy Research, Tao-Yuan, Taiwan P.G. Pagliuso11. Instituto de Física ``Gleb Wataghin’’, Universidade Estadual de Campinas, Campinas, SP, Brazil; 2. University of California, Irvine, CA 114 PROGRAM PROGRAM 115

CS-05. Pressure effect on magnetic pair-breaking in Mn and Eu- CS-12. Magnetic Properties of LaOMnAs: a First Principles substituted BaFe2As2 single crystals. P.F. Rosa1, T.M. Garitezi1, Study.S. Dong1,2, W. Li4,5, X. Huang1 and E. Dagotto2,31. C. Adriano1, T. Grant2, Z. Fisk2, R.R. Urbano1, R.M. Fernandes3 Department of Physics, Southeast University, Nanjing, Jiangsu, and P.G. Pagliuso11. Physics Institute “Gleb Wataghin”, China; 2. Department of Physics and Astronomy, University of University of Campinas, Campinas, Brazil; 2. Department of Tennessee, Knoxville, TN; 3. Materials Science and Technology Physics and Astronomy, University of California, Irvine, CA; 3. Division, Oak Ridge National Laboratory, Oak Ridge, TN; 4. School of Physics and Astronomy, University of Minnesota, Shanghai Institute of Microsystem and Information Technology, Minneapolis, MN Chinese Academy of Sciences, Shanghai, China; 5. Department of Physics, Fudan University, Shanghai, China CS-06. Magnetic structure of the high temperature superconductor 1 1 2 Gd1-xThxFeAsO.N.R. Lee-Hone , D.H. Ryan , J.M. Cadogan CS-13. Finite-size effects in the Néel temperature and optical energy and G.H. Cao31. Physics Department and Centre for the Physics gap of NiO nanoparticles. S. Thota1, H. Shim2 and M. Seehra21. of Materials, McGill University, Montreal, QC, Canada; 2. Department of Physics, Indian Institute of Technology Guwahati, School of Physical, Environmental and Mathematical Sciences, Guwahati, Assam, India; 2. Department of Physics, West Virginia UNSW Canberra at the Australian Defence Force Academy, University, Morgantown, WV Canberra, ACT, Australia; 3. Department of Physics, Zhejiang University, Hangzhou, Zhejiang, China

CS-07. Doping effects of Co on the transport and magnetic properties of FeTe.Y. Zhu1, L. Li1, Z. Yang1, Z. Zhang1, B. Yuan1, J. Chen1, WEDNESDAY EXHIBIT HALL H. Du2, Y. Sun1 and Y. Zhang21. Key Laboratory of Materials MORNING Physics, Institute of Solid State Physics, Chinese Academy of 9:30 Sciences, Hefei, Anhui, China; 2. High Magnetic Field Laboratory, Hefei Institutes of Physical Science, Chinese Session CT Academy of Sciences, Hefei, Anhui, China BIT-PATTERNED AND ENERGY-ASSISTED

CS-08. The dynamic spin reorientation process of ErFeO3 single RECORDING MEDIA crystal by AC susceptibility.H. Shen1,2, Z. Cheng2, F. Hong2, (Poster Session) X. Wang2 and J. Xu11. Shanghai Institute of Technology, Jian-Gang Zhu, Chair Shanghai, China; 2. UOW, Wollongong, NSW, Australia

CT-02. Highly Efficient Plasmonic Waveguide for both All-Optical CS-09. Anomalous Enhancement on Magnetic Ordering by Divalent Magnetic Recording and Thermally Assisted Magnetic 1 Ions Doping of (Bi0.9M0.1)FeO3 (M=Pb, Ca). C.P. Wu , H. Recording. K. Nakagawa1, K. Tamura1, Y. Ashizawa1 and 1 1 1 1 1 Chou , M. Bohra , S.R. Yah , K.S. Yang , H.W. Chang , K.C. S. Ohnuki11. Nihon University, Funabashi, Japan Liu1, M.Y. Chiang2, S.J. Sun3 and H.S. Hsu4 1. Department of Physics, National Sun Yat-sen University, Kaohsiung, Taiwan; 2. Department of Chemistry, National Sun Yat-sen University, CT-03. Simulation on Near-Field Light Generated by Au Nano-Dot 1 Kaohsiung, Taiwan; 3. Department of Applied Physics, National on GaAs Substrate for HAMR Heat Source. R. Katayama 1. University of Kaohsiung, Kaohsiung ,Taiwan; 4. Department of Department of Information Electronics, Faculty of Engineering, Applied Physics, National Pintung University of Education, Fukuoka Institute of Technology, Fukuoka, Japan Pintung, Taiwan CT-05. FePt/Fe Exchange Coupled Patterned Films using Self- 1 1 1 1 CS-10. Tunable magnetic transition by doping effect in Organized Templates.C. Deng , Y. Qi , F. Wang , X. Qin , 2 1 HoFeO3.Y. Yang1, S. Yuan1, Y. Cao1, A. Wu2, B. Lu3 and H. Zeng and X. Xu 1. Shanxi Normal University, Linfen, Shanxi, J. Zhang11. Department of Physics, Shanghai university, China; 2. University at Buffalo, the State University of New York, Shanghai, Shanghai, China; 2. Shanghai Institute of Ceramics, Buffalo, NY Chinese Academy of Sciences, Shanghai, China; 3. Laboratory for Microstructures, Shanghai University, Shanghai, China CT-06. Fabrication of ferromagnetic-paramagnetic pattern by Mn

ion implantation into [001]-oriented L10 (Fe1-xMnx)50Pt50 film. 1 1 1 2 1 CS-11. Structural, magnetic and magnetodielectric studies of T. Hasegawa , T. Yamazaki , K. Sasaki , Y. Kondo and S. Ishio 1. 1 1 Department of Materials Science and Engineering, Akita metamagnetic DyFe0.5Cr0.5O3 V.G. Nair , V. Subramanian and P.N. Santhosh11. Department of Physics, Indian Institute of University, Akita, Japan; 2. Akita Industrial Technology Center Technology Madras, Chennai, Tamil nadu, India (AIT), Akita, Japan

CT-07. Novel Read Channel Model Using Staggered Pattern for Bit Patterned Media Recording. G. Kong1 and S. Choi11. School of Electrical & Electronic Engineering, Yonsei University, Seoul, Republic of Korea 116 PROGRAM PROGRAM 117

CT-08. Numerical optimization of writer geometries for bit patterned CT-18. Exchange coupled composite Bit Patterned media for magnetic recording. A. Kovacs1, T. Schrefl1 and M.E. Schabes21. microwave assisted magnetic recording. N. Eibagi1,2, J.J. Kan1,3 Technology, St.Poelten University of Applied Sciences, Vienna, and E.E. Fullerton1,21. Center for Magnetic Recording Research, Austria; 2. HGST, San Jose, CA University of California, San Diego, La Jolla, CA; 2. Electrical and Computer Engineering, University of California, San Diego, San Diego, CA; 3. Material Science, University of California, San CT-09. A Constructive Inter-Track Interference Coding Scheme for Diego, La Jolla, CA Bit-Patterned Media Recording System.A. Arrayangkool1, C. Warisarn1 and P. Kovintavewat21. College of Data Storage Innovation, King Mongkut’s Institute of Technology Ladkrabang, CT-20. Micromagnetic simulation of shingled magnetic recording Bangkok, Thailand; 2. Nakhon Pathom Rajabhat University, combined with microwave assisted magnetization reversal. Nakhon Pathom, Thailand T. Tanaka1, S. Kashiwagi1, Y. Otsuka1, Y. Kanai2 and K. Matsuyama11. Faculty of Information Science and Electrical Engineering, Kyushu University, Fukuoka, Fukuoka, Japan; 2. CT-10. The influence of ion-milling damage to magnetic properties of IEE, Niigata Institute of Technology, Kashiwazaki, Niigata, Japan Co80Pt20 patterned perpendicular media. Z. Sun1,3, T. Mewes2,3 and D. Li1,31. Electrical and Computer Engineering, The University of Alabama, Tuscaloosa, AL; 2. Physics, The University of Alabama, Tuscaloosa, AL; 3. MINT center, The University of Alabama, Tuscaloosa, AL WEDNESDAY EXHIBIT HALL MORNING CT-11. Reader Design for Bit Patterned Media Recording at 10 Tbits/in2 Density. Y. Wang 1 and R.H. Victora11. Electrical and 9:30 Computer Engineering, University of Minnesota, Minneapolis, MN Session CU MAGNETIZATION DYNAMICS: FMR AND CT-12. Switching field distribution of bit patterned MnGa films DAMPING 1 1 1 fabricated by ion irradiation. D. Oshima , T. Kato , S. Iwata (Poster Session) and S. Tsunashima21. Graduate school of engineering, Nagoya university, Nagoya, Japan; 2. Nagoya Industry Science Research Sangita Kalarickal, Chair Institute, Nagoya, Japan CU-01. Relationship between Gilbert Damping and Exchange Bias CT-14. Switching field reduction of Co-Cr-Pt granular film under the field in Exchange-biased IrMn/Cu/CoFe Trilayer films. 1,2 3 1,2 4 4 5 assistance of rf fields. S. Okamoto1, N. Kikuchi1, A. Hotta2, H. Song , K. Lee , J. Sohn , S. Yang , S. Parkin , C. You and 1,2 M. Furuta1, O. Kitakami1 and T. Shimatsu2,31. IMRAM, Tohoku S. Shin 1. Physics, KAIST, Daejeon, Republic of Korea; 2. University, Sendai, Japan; 2. FRIS, Tohoku University, Sendai, Emerging Materials Science, DGIST, Daegu, Republic of Korea; Japan; 3. RIEC, Tohoku University, Sendai, Japan 3. Materials Science and Engineering, KAIST, Daejeon, Republic of Korea; 4. IBM Research Division, Almaden Research Center, San Jose, CA; 5. Physics, Inha University, Incheon, Republic of CT-15. Time-resolved imaging of microwave-assisted magnetization Korea reversal. S. Rao, V.N.1, J.P. Rhensius1, A. Bisig2,3, M. Mawass2,3, M. Weigand3, M. Kläui2, C.S. Bhatia1 and H. Yang11. Dept Electrical & Computer Engg., National University of Singapore, CU-02. Ferromagnetic resonance: electrical detection vs conventional 1 1 1 Singapore, Singapore; 2. Institute of Physics, Johannes Gutenberg absorption measurements. H. Seinige , C. Wang and M. Tsoi 1. University Mainz, Mainz, Germany; 3. Max-Planck-Insitut fur Physics Department, University of Texas at Austin, Austin, TX Intelligente Systeme, Stuttgart, Germany CU-03. Magnetization dynamics and interface studies in ion-beam CT-16. Microwave-assisted Magnetization Reversal in Spin Valve sputtered Si/CoFeB(8)/MgO(4)/CoFeB(8)/Ta(5) 1 1 with Magnetic Anisotropy.X. Liu1, C. Mu1, Q. Zhu1, S. Zhang1, structures.M. Raju and D. Pandya 1. Physics Departent, Indian Q. Zheng1, Q. Liu1 and J. Wang11. Key Laboratory for Institute of Technology Delhi, New Delhi, India Magnetism and Magnetic Materials of Ministry of Education, Lanzhou, China CU-04. Spin-Wave Instability Thresholds for Ultrathin Ferromagnetic Films under Microwave Pumping.H.T. Nguyen1 and 1 CT-17. Magnetic field generated by Spin Torque Oscillator and its M.G. Cottam 1. Department of Physics and Astronomy, University influence on microwave assisted recording. Y. Guo1, X. Li1, of Western Ontario, London, ON, Canada S. Niu2, W. Fu2 and Z.J. Liu31. Taiyuan University of Technology, Taiyuan, China; 2. The Hong Kong Polytechnic University, Hong Kong, Hong Kong; 3. National University of Singapore, Singapore, Singapore 118 PROGRAM PROGRAM 119

CU-05. Damping parameter in perpendicularly magnetized FeB layer CU-12. Voltage controlled FMR in ferromagnetic thin films deposited sandwiched by thin MgO barrier and cap layers in magnetic on PMNPT single crystalline substrate. X. Fan1, H. Zhou1, tunnel junctions. H. Kubota1, S. Tamaru1, T. Taniguchi1, F. Wan1, H. Shi1, X. Zhao1 and D. Xue11. The Key Lab for K. Yakushiji1, M. Konoto1, S. Tsunegi1, A. Fukushima1, S. Yuasa1, Magnetism and Magnetic Materials of Ministry of Education, H. Arai1 and H. Imamura11. National Institute of Advance Lanzhou University, Lanzhou, Gansu, China Industrial Science and Technology (AIST), Tsukuba, Japan CU-13. Control of Three-Magnon Scattering in Magnetic Thin Films CU-06. Static and dynamic magnetic properties of cubic Mn3- through Spin Transfer Torque. L. Lu1 and M. Wu11. Physics, xCoxGa Heusler thin films. A.S. Demiray1, T. Kubota2, Colorado State University, Fort Collins, CO S. Iihama1, S. Mizukami2, T. Miyazaki2, H. Naganuma1, M. Oogane1 and Y. Ando11. Applied physics, Tohoku university, CU-14. Dependence of nonlinear resonance shift on field and Sendai, Japan; 2. Advanced institute for materials reserach, anisotropy in Permalloy nanomagnets. F. Guo1,2, L. Belova3 Tohoku University, Sendai, Japan and R. McMichael11. Center for Nanoscale Science and Technology, National Institute of Standards and Technology, CU-07. Ferromagnetic resonance of perpendicular magnetic Gaithersburg, MD; 2. Maryland Nanocenter, University of anisotropy MgO/CoFeB-based tri-layers. Y. Aleksandrov1,2, Maryland, College Park, MD; 3. Department of Materials C. Fowley1, K. Bernert1,2, V. Sluka1, E. Kowalska1,2, M. Farle3, Science and Engineering, Royal Institute of Technology, J. Lindner1, B. Ocker4, J. Fassbender1,2 and A. Deac11. HZDR, Stockholm, Sweden Dresden, Germany; 2. TU Dresden, Dresden, Germany; 3. Universität Duisburg- Essen, Duisburg, Germany; 4. Singulus CU-15. Three-magnon process in magnetic tunnel junction Technologies AG, Kahl am Main, Germany nanopillars. I. Barsukov1, A.M. Gonçalves1,2, Y. Chen1, J.A. Katine3 and I.N. Krivorotov11. Physics and Astronomy, CU-08. Large Spin Pumping and Characterization of inverse spin University of California, Irvine, CA; 2. CBPF, Rio de Janeiro, Hall effect from Y3Fe5O12 Thin Films to Pt, Ta, W, Au, Ag Brazil; 3. HGST Research Center, San Jose, CA and Cu Layers. H. Wang1, C. Du1, Y. Pu1, R. Adur1, C.P. Hammel1 and F. Yang11. Physics, The Ohio State University, CU-16. Biasing field direction effect on the spin wave modes in Columbus, OH micron-scale ferromagnetic wires.E. Caldwell1, A. Grant1 and A. Kozhanov11. Physics and Astronomy, Georgia State University, CU-09. Magnetization dynamics in RKKY-coupled metallic trilayers. Atlanta, GA Y. Wei 1, S. Jana2, R. Brucas1, M. Ranjbar3, R.K. Dumas3, P. Warnicke4, J. Åkerman3,5, D.A. Arena6, O. Karis2 and P. Svedlindh11. Engineering Sciences, Uppsala University, Uppsala, Sweden; 2. Physics and Astronomy, Uppsala University, Uppsala, Sweden; 3. Physics, University of Gothenburg, WEDNESDAY EXHIBIT HALL Gothenburg, Sweden; 4. Swiss Lightsource SLS, Paul Scherrer MORNING Institut, Villigen, Switzerland; 5. Materials Physics, Royal Institute of Technology, Stockholm, Sweden; 6. National 9:30 Synchrotron Light Source, Brookhaven National Lab, Upton, NY, NY Session CV ENERGY HARVESTING, GENERATORS, AND CU-10. Ferromagnetic resonance linewidth and enhanced damping in LEVITATION Tb-doped Ni Fe thin films.C. Luo1, D. Zhang1,3, Y. Wang1, 80 20 (Poster Session) H. Huang2, Y. Zhai1 and H. Zhai41. Department of Physics, Southeast University, Nanjing, China; 2. Department of Material S.G. Sankar, Chair Science and Engineering, Southeast University, Nanjing, China; 3. School of Physics Science and Information Engineering, CV-01. Electromagnetic Analysis and Experimental Testing of Light Liaocheng University, Liaocheng, China; 4. National Laboratory Switch with Permanent Magnet Generator for Energy of Solid Microstructures, Nanjing University, Nanjing, China Harvesting based on 3D FEM. H. Shin1, J. Choi1, I. Kim2 and Y. Choi21. Chungnam National University, Dae-jeon, Republic of Korea; 2. Hoseo University, Asan, Chungnam, Republic of Korea CU-11. Magnetization Damping of an L10-FeNi Thin Film with Perpendicular Magnetic Anisotropy. T. Seki1, M. Ogiwara1, 2 1 3 1 S. Iihama , T. Kojima , S. Mizukami , M. Mizuguchi and CV-02. Investigation of Energy Harvesting for Magnetic Sensor 1 K. Takanashi 1. Institute for Materials Research, Tohoku Array in Mars by Wireless Power Transmission. C. Liu1, University, Sendai, Japan; 2. Graduate School of Engineering, K. Chau1, C. Qiu1 and F. Lin11. Department of Electrical and Tohoku University, Sendai, Japan; 3. WPI Advanced Institute for Electronic Engineering, The University of Hong Kong, Hong Materials Research, Tohoku University, Sendai, Japan Kong, China 120 PROGRAM PROGRAM 121

CV-03. Conceptual Design of Rotary Magnetostrictive Energy CV-13. Torque Analysis and Measurements of Permanent Magnet Harvester. Y. Park1,3, H. Kang2 and N.M. Wereley31. Type Eddy Current Brake with Halbach Magnet Array Based Mechatronics Engineering, Chungnam Natational University, on Analytical Magnetic Field Calculations. M. Park1, J. Choi1 Daejeon, Republic of Korea; 2. Mechatronics Engineering, and H. Shin11. Chungnam National University, Dae-jeon, Chungnam National University, Daejeon, Republic of Korea; 3. Republic of Korea Aerospace Engineering, University of Maryland, College Park, MD CV-14. Design and Transient Behaviour of Magnetic Gears. P. Zheng1, J. Bai1, J. Lin1, C. Tong1 and Z. Song11. Department of Electrical CV-04. A feasibility study on a new brushless and gearless contra- Engineering, Harbin Institute of Technology, Harbin, rotating permanent magnet wind power generator. S. Niu1, Heilongjiang, China S. Ho1 and W. Fu11. the Hong Kong Polytechnic University, Hong Kong, Hong Kong CV-15. Optimal Design of a New Magnetic Variable Gear with Controllable Gear Ratio. M. Chen1, K. Chau1, C. Liu1, W. Li1, CV-05. A transverse flux machine for power generation from C. Qiu1 and F. Lin11. Department of Electrical and Electronic seawaves. A. Viola1, M. Trapanese1 and V. Franzitta11. DEIM, Engineering, The University of Hong Kong, Hong Kong, Hong Palermo University, Palermo, Italy Kong

CV-06. Development of a Super High Speed Motor-generator and CV-16. Tunable Viscosity and Magnetoconvection Effects of Vegetable Controller. D. Hong1, D. Joo1, B. Woo1 and D. Koo11. Korea Transformer Oil with Magnetic Nanoparticles.H. Lee1 and Electrotechnology Research Institute, Changwon, Republic of S. Lee11. School of Electrical Eng. and Computer Science, Korea Kyungpook National Univ., Daegu, Republic of Korea

CV-07. A Novel Single-Phase Flux-Switching Permanent Magnet Linear Generator Used for Free-Piston Stirling Engine. P. Zheng1, Y. Sui1, C. Tong1, J. Bai1 and B. Yu11. School of Electrical Engineering and Automation, Harbin Institute of WEDNESDAY PLAZA BALLROOM A Technology, Harbin, Heilongjiang, China MORNING 9:30 CV-08. Improvement of Thrust Force of Linear Synchronous Motor for High-Speed Maglev Train. S. Oh1, H. Lee1, G. Ryu1 and Session CW J. Lee11. Electrical Enginnering, Hanyang University, Seoul, METALLIC, NON-OXIDE, AND CORE-SHELL Republic of Korea NANOPARTICLES (Poster Session) CV-09. Investigation of Cross-Coupling Inductances for Long-stator PM Linear Motor Arranged in Multiple Segments. M. Ma1 and Ryan Booth, Chair L. Li11. Department of Electrical Engineering, Harbin Institute of Technology, Harbin, China CW-01.Templated Fabrication and Characterization of SiO2 Nanotube Covered Fe Nanowires. H. Yu11. Arizona State CV-10. Analysis and Comparison of Two 2-D Halbach Permanent University, Tempe, AZ Magnet Arrays for Magnetically Levitated Planar Motor. 1 1 1 L. Zhang , B. Kou and F. Xing 1. Department of Electrical CW-02.Oxide Shell Reduction and Magnetic Property Changes in Engineering, Harbin Institute of Technology, Harbin, Hei Core-Shell Fe Nanoclusters under Ion Irradiation. Longjiang, China J. Sundararajan1, M. Kaur1, W. Jiang2, J.S. McCloy2 and Y. Qiang11. Physics, University of Idaho, Moscow, ID; 2. Pacific CV-11. Transverse End Effect for HTS Electrodynamic Levitation Northwest National Laboratory, Richland, WA Device. S. Li1, Y. Fan1 and X. Zhu21. School of Eleltrical Engieering, Beijing Jiaotong University, Beijing, Beijing, China; CW-03.Structural Phase Transformation of Nickel Nanostructures 2. Department of Electrical and Computer Engineering, with Synthetic Approach Conditions. B.C. Behera1, University of New Brunswick, Fredericton, NB, Canada V. Annavarapu1 and P. Padhan11. Department of Physics, Indian Institute of Technology Madras, Chennai, Chennai, Tamilnadu, CV-12. Modeling and analysis of a novel 2-DOF planar India electromagnetic damper. H. Zhang1, B. Kou1, Y. Jin1 and H. Zhang11. Electric Engineering, Harbin Institute of Technology, Harbin, Heilongjiang, China 122 PROGRAM PROGRAM 123

CW-04.Magnetization analysis of oriented chains of hexagonal cobalt WEDNESDAY PLAZA BALLROOM A nano-plates.E. Vargas1,4, P. Mascaró2, R. Lavín3, C. Chaneac4, 4 2 MORNING T. Coradin and J. Denardin 1. Depto. Ingeniería Metalúrgica, 9:30 Universidad de Santiago, Santiago, Chile; 2. Departamento de Fisica, Universidad de Santiago, Santiago, Chile; 3. Facultad Ingeniería, Universidad Diego Portales, Santiago, Chile; 4. Session CX LCMCP, Université Pierre et Marie, Curie Paris VI, Collège de HEXAFERRITES AND GARNETS France, Paris, France (Poster Session) Ogheneyunume Obi, Chair CW-05.Preparation and magnetic properties of Ag@ Ni core–shell nanoparticles. T. Ger1, W. Liu1, Z. Wei1 and C. Huang11. National Tsing Hua University, Hsinchu, Taiwan CX-01. The transformation behavior of M-type barium ferrites due to Co-Ti substitution. J. Li1, H. Zhang1, Q. Li1, Y. Li1, G. Yu1 and T. Zhou11. State Key Laboratory of Electronic Thin Films and CW-06.Using Co2C as a template for the synthesis of Co@C Integrated Devices, University of Electronic Science and 1 1 nanoworms. Z.J. Huba and E.E. Carpenter 1. Virginia Technology of China, Cheng Du, Sichuan province, China Commonwealth Universtiy, Richmond, VA

CX-02. Magnetic properties of Ni substituted Y-type Barium Ferrite. CW-07.Tight Waist Hysteresis Loop of Cr-Doped Core-Shell Fe M. Won1 and C. Kim11. Physics, Kookmin University, Seoul, 1 1 Nanoclusters. M. Kaur and Y. Qiang 1. Physics, University of Republic of Korea Idaho, Moscow, ID

CX-03. The crystal structure and magnetic properties of Ba2- CW-08.Stabilizing Vortices in Interacting core-shell structure with Sr Co Fe O K. Cho1, C. Rhee1 and C. Kim11. Department of 1,2 1 x x 2 12 22 AC field. M. Yang and C. Lai 1. Department of Materials Physics, Kookmin University, Seoul, Republic of Korea Science and Engineering, National Tsing Hua University, Hsinchu, Taiwan; 2. Material and Chemical Research Laboratories, Industrial Technology Research Institute, Hsinchu, CX-04. Optical and magnetooptical spectroscopic studies of BaFe12O19 Taiwan films grown by metallo-organic decomposition. E.L. Jakubisova1, S. Visnovsky1, P. Siroky2, D. Hrabovsky2, J. Pistora2, P. Kristan1, H. Stepankova1, I. Harward3 and α 3 CW-09.Growth mechanism and magnetic properties of the -FeSe Z. Celinski 1. Faculty of Mathematics and Physics, Charles 1 1 1 1 1 nanostructures.D. Li , S. Li , J. Jiang , S. Ma , W. Liu and University in Prague, Prague, Czech Republic; 2. 1 Z. Zhang 1. institute of metal research, Shenyang, Liaoning, Nanotechnology Centre, Technical University of Ostrava, China Ostrava-Poruba, Czech Republic; 3. Center for Magnetism and Magnetic Nanostructures, University of Colorado at Colorado Springs, Colorado Springs, CO CW-10.High frequency study of core–shell reusable CoFe2O4–ZnO nano-sized hollow spheres. B.K. Kuanr1,2, S.R. Mishra3, A.V. Kuanr4 and Z. Celinski21. Electronics Department, Zakir CX-05. Magnetic properties of Zn doped Co2Y hexaferrite by using Husain Delhi College (University of Delhi), Delhi, India; 2. high-field Mössbauer spectroscopy. J. Lim1, H. Noh1 and Department of Physics, University of Colorado at Colorado C. Kim11. Physics, Kookmin University, Seoul, Republic of Korea Springs, Colorado Springs, CO; 3. Physics Department, University of Memphis, Memphis, TN; 4. Physics Department, Shaheed Rajguru College of Applied Sciences For Women CX-06. Characterization and growth of perpendicularly self-biased 1 1 1 (University of Delhi), Delhi, India W-type hexaferrite thin films. Z. Su , Y. Chen , S. Bennett , B. Hu1 and V.G. Harris11. Northeastern University, boston, MA

CX-07. Structural and Magnetic Properties of Y-type Hexaferrite Thin Films Grown at the Atomic Scale. M. Mohebbi1, K. Ebnabbasi1 and C. Vittoria11. Northeastern University, Boston, MA

CX-08. Permeability Measurement of Magnetoelectric Thin Film Using a Microstrip. M. Mohebbi1, K. Ebnabbasi1 and C. Vittoria11. Northeastern University, Boston, MA

CX-09. Magnetic, microwave properties and structure of Y-type hexaferrite single crystal epitaxial grown on GaN/Al2O3 substrate. B. Hu1, Y. Chen1, S. Gillette1, Z. Su1, S. Bennett1, Z. Chen2 and V. Harris11. Northeastern University, Boston, MA; 2. Intel Corp Extreme Technology Research Lab, Santa Clara, CA 124 PROGRAM PROGRAM 125

CX-10. Microwave and magnetic properties of Al-doped M-type 2:42 barium hexaferrite thick films by tape casting.D. Chen1, Y. Liu1, Y. Li1, J. Li1 and H. Zhang11. School of Microelectronics DA-03. Non linear spin transfer induced vortex dynamics. (Invited) J. Grollier1, V. Cros1, A. Dussaux1, P. Bortolotti1, E. Grimaldi1, and Solid-State Electronics, University of Electronic Science and 2 2 3 3 Technology of China, Chengdu, Sichuan, China A. Khvalkovskiy , K.A. Zvezdin , A. Fukushima , H. Kubota , K. Yakushiji3, S. Yuasa3 and A. Fert11. Unité Mixte CNRS/Thales, Palaiseau, France; 2. A.M. Prokhorov GPI, Moscow, Russian CX-11. Synthesis and Magnetic Properties of exchange-coupled Federation; 3. National Institute of Advanced Industrial Science SrFe12O19 - x Wt.%- La0.7Sr0.3MnO3 nanocomposites via and Technology (AIST), Tsukuba, Japan autocombusiton method Jiba Nath Dahal and S. R. Mishra The Department of Physics, The University of Memphis, Memphis, TN 38152. J.N. Dahal11. Physics, The University of 3:18 Memphis, Memphis, TN DA-04. Microwave spectroscopy of spin Hall nano-oscillators. (Invited) S. Urazhdin1, R. Liu1, W.L. Lim1, V.E. Demidov2 and 2 CX-12. Growth of Nanometer-Thick Yttrium Iron Garnet Films by S.O. Demokritov 1. Physics, Emory University, Atlanta, GA; 2. Sputtering. T. Liu1,2, H. Chang1, Y. Sun1, M. Kabatek1, L. Deng2 University of Muenster, Muenster, Germany and M. Wu11. Physics, Colorado State University, Fort collins, CO; 2. State Key Laboratory of Electronic Thin Films and 3:54 Integrated Devices, University of Electronic Science and Technology of China, Chengdu, Sichuan, China DA-05. Nonlinear dynamics of magnetic vortices induced by spin- transfer torque. (Invited) A. Slavin1, F. Sanches1, V. Tiberkevich1 and K. Guslienko2,31. Physics, Oakland University, Rochester, MI; 2. Fisica de Materiales, Universidad del Pais Vasco, Donostia, Spain; 3. IKERBASQUE, The Basque Foundation of Science, WEDNESDAY PLAZA BALLROOM BC Bilbao, Spain AFTERNOON 1:30

Session DA WEDNESDAY PLAZA BALLROOM F SYMPOSIUM ON NONLINEAR AFTERNOON MAGNETIZATION DYNAMICS INDUCED BY 1:30 SPIN-TRANSFER TORQUE Session DB Zbigniew Celinski, Chair DOMAIN WALL DYNAMICS Alex Reid, Chair 1:30 DA-01. Spin Transfer Torque Generated Magnetic Droplet Solitons. 1:30 (Invited) J. Åkerman1,2, S.M. Mohseni3,2, S.R. Sani2,3, T.N. Anh Nguyen2, S. Chung2,1, Y. Pogoryelov1, P.K. Muduli1,4, E. Iacocca1, DB-01. Magnetization reversal and domain wall motion in A. Eklund2, R.K. Dumas1, S. Bonetti5, A. Deac6 and ferromagnetic nanotubes. (Invited) P. Landeros11. M.A. Hoefer71. Univ Gothenburg, Göteborg, Sweden; 2. KTH Departamento de Física, Universidad Técnica Federico Santa Royal Institute of Technology, Kista, Sweden; 3. NanOsc AB, María, Valparaiso, Valparaíso, Chile Kista, Sweden; 4. Indian Institute of Technology Delhi,, Delhi, India; 5. Stanford University, Stanford, CA; 6. Helmholtz-Zentrum 2:06 Dresden-Rossendorf e.V., Dresden, Germany; 7. North Carolina State University, Raleigh, NC DB-02. Time-resolved imaging of the fast domain-wall nucleation and annihilation in nanowires. F. Stein1, L. Bocklage1,2, M. Weigand3 and G. Meier1,41. Institut für Angewandte Physik und Zentrum für 2:06 Mikrostrukturforschung, Universität Hamburg, Hamburg, DA-02. Theory of magnetic droplet solitons. (Invited) M. Hoefer1, Germany; 2. Deutsches Elektronen-Synchrotron, Hamburg, T.J. Silva2, M. Keller2, M. Sommacal3, L. Bookman1 and Germany; 3. Max-Planck-Institut fuer Intelligente Systeme, M. Maiden41. Mathematics, NC State University, Raleigh, NC; 2. Stuttgart, Germany; 4. The Hamburg Centre for Ultrafast NIST, Boulder, CO; 3. Northumbria University, Northumbria, Imaging, Hamburg, Germany United Kingdom; 4. Meredith College, Raleigh, NC 126 PROGRAM PROGRAM 127

2:18 3:30 DB-03. Identification and motion of domain walls in cylindrical DB-09. Resonant modes of pinned transverse domain walls. nanowires.S. Da-Col1, S. Jamet1, N. Rougemaille1, A. Locatelli2, P. Metaxas1,2, S. Lequeux1, P. Bortolotti1, A. Anane1, J. Grollier1 T.O. Mentes2, B. Santos Burgos2, R. Afid1, M. Darques1, and V. Cros11. Unité Mixte de Physique CNRS/Thales and L. Cagnon1, J. Toussaint1 and O. Fruchart11. Institut NEEL, Université Paris Sud, Palaiseau, France; 2. School of Physics, CNRS and Université Joseph Fourier, Grenoble, France; 2. University of Western Australia, Crawley, WA, Australia Elettra - Sincrotrone Trieste S.C.p.A., Trieste, Italy 3:42 2:30 DB-10. Beyond the Walker breakdown on a current-driven domain- DB-04. Domain wall motion in antiferromagnetically coupled wall motion. K. Lee1, D. Jeong1, H. Han1, S. Lee1 and M. Jang11. nanowires. M. Kuteifan1, M. Lubarda1,3, S. Fu1, R. Chang1, School of Mechanical & Advanced Material Engineering, Ulsan M. Escobar1, S. Mangin2, E. Fullerton1 and V. Lomakin11. ECE, National Institute of Science Technology, Ulsan, Republic of UCSD, San Diego, CA; 2. IJL Universite de Lorraine, Nancy, Korea France; 3. Polytechnics, University of Donja Gorica, Podgorica, Montenegro 3:54

2:42 DB-11. Lorentz imaging of domain wall motion and pinning exchange biased multilayers.F. Gonçalves1, G. Paterson1, S. O’Reilly2, DB-05. Domain wall tilting in out-of-plane magnetized magnetic R.M. Bowman2, D. McGrouther1, K. O’Shea1, S. McVitie1 and tracks in the presence of Dzyaloshinskii-Moriya interaction. R. Stamps11. SUPA-School of Physics and Astronomy, University O. Boulle1, S. Rohart3, L.D. Buda-Prejbeanu1, E. Jué2, M. Miron1, of Glasgow, Glasgow, United Kingdom; 2. ANSIN, Department of S. Pizzini2, J. Vogel2, G. Gaudin1 and A. Thiaville31. Spintec, Physics and Astronomy, Queen’s University of Belfast, Belfast, CEA/CNRS/UJF/INPG, Grenoble, France; 2. Institut Néel, CNRS, United Kingdom Grenoble, France; 3. Laboratoire de Physique des Solides, Université Paris Sud, CNRS UMR 8502, ORSAY, France 4:06

2:54 DB-12. Time-resolved Kerr microscopy of coupled transverse domain walls in a pair of curved nanowires. P.S. Keatley1, W. Yu1, DB-06. Symmetry Breaking in Field-Driven Domain-Wall Motion by L. O’Brien2,3, D. Read4,5, R.P. Cowburn3 and R.J. Hicken11. the Dzyaloshinskii-Moriya Interaction. S. Je1, D. Kim1, School of Physics and Astronomy, University of Exeter, Exeter, S. Yoo1,2, B. Min2, K. Lee3,4 and S. Choe11. Center for United Kingdom; 2. Chemical Engineering and Materials Subwavelength Optics and School of Physics and Astronomy, Science, University of Minnesota, Minneapolis, MN; 3. Cavendish Seoul National University, Seoul, Republic of Korea; 2. Center for Laboratory, University of Cambridge, Cambridge, United Spintronics Research, Korea Institute of Science and Technology, Kingdom; 4. School of Physics and Astronomy, University of Seoul, Republic of Korea; 3. Department of Materials Science and Cardiff, Cardiff, United Kingdom; 5. Blackett Laboratory, Engineering, Korea University, Seoul, Republic of Korea; 4. KU- Imperial College London, London, United Kingdom KIST Graduate School of Converging Science and Technology, Korea University, Seoul, Republic of Korea 4:18

3:06 DB-13. Correlated velocity and domain wall spin structure oscillations. A. Bisig1,3, M. Mawass1,3, J. Kim1,2, M. Noske3, DB-07. Field and current induced motion of Dzyaloshinskii domain M. Weigand3,4, H. Stoll3, G. Schütz3, C. You5 and M. Klaeui1,21. walls. S. Rohart1, A. Thiaville1, J. Miltat1, E. Jué2, O. Boulle2, Physics, University of Mainz, Mainz, Germany; 2. University of V. Cros3 and A. Fert31. Laboratoire de Physique des Solides, Konstanz, Konstanz, Germany; 3. Max Planck Institute for Université Paris-Sud/CNRS, Orsay, France; 2. SPINTEC, Intelligen Systems, Stuttgart, Germany; 4. BESSY, Berlin, CEA/CNRS/UJF/Grenoble-INPG, Grenoble, France; 3. Unité Germany; 5. Inha University, Incheon, Republic of Korea Mixte de Physique, CNRS/Thales, Palaiseau, France

3:18 DB-08. Chirality sensitive domain-wall motion using pulsed in-plane magnetic fields in perpendicularly magnetized strips. J. Kim1, Y. Yin 1, J. Franken1, J. Yoon2, C. You2, B. Koopmans1 and H. Swagten11. Department of Applied Physics, Center for NanoMaterials, Eindhoven, Netherlands; 2. Department of Physics, Inha University, Incheon, Republic of Korea 128 PROGRAM PROGRAM 129

WEDNESDAY PLAZA BALLROOM E 2:54 AFTERNOON DC-06. Statistical analysis of switching field and switching current 1:30 distributions of in-plane magnetized MgO-MTJs. H. Imamura1, A. Fukushima1, T. Taniguchi1, H. Arai1, S. Tamaru1, Session DC H. Ohtori1, K. Yakushiji1, H. Kubota1 and S. Yuasa11. Spintronics TUNNEL MAGNETORESISTANCE I Research Center, AIST, Tsukuba, Japan Guohan Hu, Chair 3:06

1:30 DC-07. Paramagnetic alloys for optimization of perpendicularly magnetized tunnel junctions.M. Gottwald1,2, K. Lee1, J. Kan2, DC-01. MTJ resistance distribution of 1-kbit 1T-1MTJ STT-MRAM S.H. Kang1 and E.E. Fullerton21. Advanced Technology, 1 cell arrays fabricated on a 300-mm wafer. H. Koike , Qualcomm Inc., San Diego, CA; 2. Center for Magnetic 1 2 2 1 1 1 T. Ohsawa , S. Miura , H. Honjo , S. Ikeda , T. Hanyu , H. Ohno Recording Research, University of California San Diego, San 1 and T. Endoh 1. Tohoku University, Sendai, Miyagi, Japan; 2. Diego, CA NEC Corporation, Tsukuba, Ibaraki, Japan

3:18 1:42 DC-08. Switching current of perpendicular STT-MRAM in the DC-02. Interface structure of CoFeB/MgO magnetic tunnel junctions thermally-activated regime. A.V. Khvalkovskiy1, V. Voznyuk1, 2 from hard x-ray photoelectron spectroscopy.S. Mukherjee , S. Schafer1, D. Apalkov1, R.S. Beach1, V. Nikitin1 and 1,3 4 5,2 2 6 R. Knut , J. Persson , A. Sahoo , B. Pal , S. Thiess , M. Krounbi11. Semiconductor R&D (New Memory Technology), 7 5 6 3,4 1 M. Gorgoi , P. Anilkumar , W. Drube , J. Åkerman , O. Karis Samsung Electronics, Milpitas, CA and D.D. Sarma21. Department of Physics and astrononomy, Uppsala University, Uppsala, Sweden; 2. Solid State and Structural Chemistry Unit, Indian Institute of Science, Bangalore, 3:30 India; 3. Department of Physics, University of Gothenburg, DC-09. Temperature dependence of thermal stability factor of CoFeB- Bangalore, Sweden; 4. Department of Microelectronics and MgO magnetic tunnel junctions with perpendicular easy-axis. Applied Physics, Royal Institute of Technology, Stockholm, H. Sato1, Y. Takeuchi2,3, K. Mizunuma3, S. Ishikawa3, Sweden; 5. Department of Physics, Indian Institute of Science, M. Yamanouchi1,3, S. Ikeda1,3, S. Fukami1, F. Matsukura2,1 and Bangalore, India; 6. DESY, Hamburg, Germany; 7. BESSY II, H. Ohno1,21. Center for Spintronics Integrated Systems, Tohoku Helmholtz Zentrum Berlin, Berlin, Germany University, Sendai, Miyagi, Japan; 2. WPI Advanced Institute for Materials Research (WPI-AIMR), Tohoku University, Sendai, 1:54 Miyagi, Japan; 3. Laboratory for Nanoelectronics and Spintronics, Research Institute of Electrical Communication, DC-03. Low voltage switchable perpendicularly magnetized Tohoku University, Sendai, Miyagi, Japan FeB/MgO/FeB magnetic tunnel junctions. A. Fukushima1, K. Yakushiji1, H. Imamura1, M. Konoto1, H. Kubota1, K. Ando1 and S. Yuasa11. Spintronic Reseach Center, AIST, Tsukuba, Japan 3:42 DC-10. Co/Pt multilayer-based magnetic tunnel junctions with thin Ta 1 2 1,2 2:06 spacer layer. S. Ishikawa , H. Sato , M. Yamanouchi , S. Ikeda1,2, S. Fukami2, F. Matsukura3,2 and H. Ohno1,21. DC-04. Spin and symmetry resolved photoemission to study coherent Laboratory for Nanoelectronics and Spintronics, Research tunneling in FeCo-MgO(001) based magnetic tunnel Institute of Electrical Communication, Tohoku University, Sendai, 1 1 1 2 junctions. (Invited) S. Andrieu , T. Hauet , F. Bonell , F. Bertran , Japan; 2. Center for Spintronics Integrated Systems, Tohoku 2 2 3 P. Le Fevre , A. Taleb and L. Calmels 1. Jean Lamour Institute, University, Sendai, Japan; 3. WPI Advanced Institute for Lorraine University, Vandoeuvre, France; 2. SOLEIL synchrotron, Materials Research, Tohoku University, Sendai, Japan CNRS, St Aubin, France; 3. CEMES, CNRS, Toulouse, France

3:54 2:42 DC-11. Molecular Spintronics with Self-Assembled Monolayers. DC-05. Giant tunnel magnetoresistance at room temperature in a M. Galbiati1, S. Tatay Aguilar1,2, C. Barraud1, K. Bouzehouane1, 1 1 1 1 1 cubic monocrystallne Al2O3-based magnetic tunnel junction. C. Deranlot , E. Jacquet , A. Fert , P. Seneor , R. Mattana and 1 1 1 H. Sukegawa , K. Inomata and S. Mitani 1. Magnetic Material F. Petroff11. Unité Mixte de Physique CNRS/Thales, Palaiseau Unit, National Institute for Materials Science (NIMS), Tsukuba, Cedex, France; 2. Instituto de Ciencia Molecular, Valencia, Spain Ibaraki, Japan 130 PROGRAM PROGRAM 131

4:06 1:54 DC-12. The Application of Self-Assembled Monolayers in Organic DD-03. Crystallites of Magnetic Charges in Artificial Spin Ice. Spin Valves for Molecular-Level Spintronics. J. Hong1, I. Gilbert1, S. Zhang2,3, C. Nisoli4, G. Chern4, M.J. Erickson5, S. Chang1, P. Yih1, H. Shiu2, C. Chen2 and M. Lin1,31. Department L. O’Brien5,6, C. Leighton5, P.E. Lammert2, V.H. Crespi2 and of Physics, National Taiwan University, Taipei, Taiwan; 2. P. Schiffer1,21. Physics, University of Illinois at Urbana- National Synchrotron Radiation Research Center, Hsinchu, Champaign, Urbana, IL; 2. Physics, The Pennsylvania State Taiwan; 3. Institute of Atomic and Molecular Sciences, Academia University, State College, PA; 3. Argonne National Laboratory, Sinica, Taipei, Taiwan Argonne, IL; 4. Los Alamos National Laboratory, Los Alamos, NM; 5. Chemical Engineering and Materials Science, University of Minnesota, Minneapolis, MN; 6. Cavendish Laboratory, 4:18 University of Cambridge, Cambridge, United Kingdom DC-13. Concentration dependence of the tunnel magnetoresistance and spin-transfer torque in FeCo/MgO/FeCo tunnel junctions. 2:06 C. Franz1, M. Czerner1 and C. Heiliger11. I. Physikalisches Institut, Justus-Liebig-Universitaet Giessen, Giessen, Germany DD-04. Artificial Spin Ice: Studying Frustration, Emergent Magnetic Monopoles and Thermal Behavior with Dipolar Coupled Nanomagnets. (Invited) L. Heyderman1,21. Laboratory for Mesoscopic Systems, Department of Materials, ETH Zurich, Switzerland; 2. Laboratory for Micro- and Nanotechnology, Paul WEDNESDAY PLAZA BALLROOM D Scherrer Institute, Villigen PSI, Switzerland AFTERNOON 1:30 2:42 DD-05. Imaging Real Thermodynamics of Artificial Spin Ice using Session DD Transmission Xray Microscopy (TXM). S.A. Morley1, A. Stein2, FRUSTRATED MAGNETISM AND CRITICAL D. Alba Venero3, S. Langridge3, A. Hrabec1 and C.H. Marrows11. PHENOMENA School of Physics and Astronomy, University of Leeds, Leeds, United Kingdom; 2. Centre for Functional Nanomaterials, Robert Stamps, Chair Brookhaven National Laboratory, Upton, NY; 3. STFC Rutherford Appleton Lab, ISIS, Didcot, United Kingdom 1:30 DD-01. Direct observation of thermal relaxation in artificial spin ice. 2:54 1,2 1 1 1 A. Farhan *, P.M. Derlet , A. Kleibert , A. Balan , DD-06. Spin-Liquid Order via Chiral Loops in Artificial Quasicrystal 1 1,2 1,3 1,4 R.V. Chopdekar , L. Anghinolfi , M. Wyss , J. Perron , Spin Ice. L.E. De Long1, V. Bhat1, B. Farmer1, J. Woods1, 5 1 1,2 A. Scholl , F. Nolting and L.J. Heyderman 1. Paul Scherrer J.T. Hastings1, J. Sklenar2 and J.B. Ketterson21. Physics and Institute, Villigen, Aargau, Switzerland; 2. Department of Astronomy, University of Kentucky, Lexington, KY; 2. Physics and Materials, Laboratory for Mesoscopic Systems, Department of Astronomy, Northwestern University, Evanston, IL Materials, ETH Zurich, 8093 Zürich, Switzerland; 3. Swiss Nanoscience Institute, University of Basel, Klingelbergstrasse 82, 4056 Basel, Switzerland; 4. Laboratoire de Chimie Physique - 3:06 Matiere et Rayonnement, UMR 7614, UPMC, Paris, France; 5. DD-07. In Search of the Origin of Glassiness in La0.85Sr0.15CoO3 Lawrence Berkeley National Laboratory (LBNL), 1 Cyclotron 1 2 3 3 1 K. Manna , D. Samal , A.K. Bera , S.M. Yusuf , S. Elizabeth and Road, Berkeley, CA 1 P.S. Anil Kumar 1. Department of Physics, Indian Institute of Science, Bangalore, Karnataka, India; 2. Faculty of Science and 1:42 Technology, MESA + Institute for Nanotechnology, Enschede, Netherlands; 3. Solid state physics Division, Bhaba Atomic 1 1 DD-02. Artificial Magnetic Quasi-crystal. D. Shi , P. Olmsted , Research Centre, Mumbai, Maharastra, India G. Burnell1, C. Marrows1 and A. Stein21. University of Leeds, Leeds, United Kingdom; 2. Brookhaven National Laboratory, New York, NY 3:18 DD-08. Re-entrant Spin-Glass State in a Geometrical Frustrated System: Role of Disorder. S. Majumdar1 and S. Chattopadhyay11. Solid State Physics, Indian Association for the Cultivation of Science, Kolkata, West Bengal, India 132 PROGRAM PROGRAM 133

3:30 WEDNESDAY GOVERNOR’S SQ 14 DD-09. Dynamics influencing thermodynamics of an Ising AFTERNOON Antiferromagnetic on a triangular lattice. G.A. Gehring1, 1:30 C. Bentham1 and S. George11. Physics and Astronomy, University of Sheffield, Sheffield, S. Yorkshire, United Kingdom Session DE MAGNETIC NANOPARTICLES I 3:42 Frank Zhu, Chair 1 1,2 DD-10. Generalized Kondo Effect in Mn3Ga. R. Skomski , P. Kharel , 2 1 Y. Huh and D.J. Sellmyer 1. Physics and Astronomy, Univ 1:30 Nebraska, Lincoln, NE; 2. Department of Physics, South Dakota State University, Brookings, ND DE-01. On the correlation of the nanostructure of magnetic nanoparticles to their physical properties. (Invited) X. Batlle1, A. Labarta1, N. Perez1, A. Fraile Rodriguez1, C. Moya1, 3:54 O. Iglesias1, A.I. Figueroa2, F. Bartolome2, L.M. Garcia2, J. Bartolome2, C.J. Serna3, M.P. Morales3, J. Salafranca4,5, DD-11. Vacancies induced magnetic ordering in YCo2 Pauli 4,5 5 5,4 6 paramagnet.M. Werwinski1, Z. Sniadecki1, A. Szajek1, J. Gazquez , S.J. Pennycook , M. Varela and S.T. Pantelides 1. U. Rössler2 and B. Idzikowski11. Institute of Molecular Physics Department of Fundamental Physics and Institute of Nanoscience PAS, Poznan, Poland; 2. IFW Dresden, Dresden, Germany and Nanotechnology, Universitat de Barcelona, Barcelona, Spain; 2. ICMA-CSIC-Universidad de Zaragoza, Zaragoza, Spain; 3. ICMM-CSIC, Madrid, Spain; 4. Universidad Complutense de 4:06 Madrid, Madrid, Spain; 5. Oak Ridge National Laboratory, Oak Ridge, TN; 6. Vanderbilt University, Nashville, TN DD-12. 3d-4f spin interaction and field-induced metamagnetism in RXO4 (R=Ho, Gd, Lu; X=Cr, V) compounds. P. Mandal1 and A. Midya11. Experimental Condensed Matter Physics, Saha 2:06 Institute of Nuclear Physics, Calcutta, India DE-02. Effective Energy Barrier Distributions for Random and Aligned Magnetic Nanoparticles.J. Eloi1, M. Okuda1, 4:18 S. Carreira1, W. Schwarzacher1, M. Correia2 and W. Figueiredo21. H H Wills Physics Laboratory, University of Bristol, Bristol, DD-13. The critical behaviour and magnetism of MnCoGe Al 1-x x United Kingdom; 2. Departamento de Física, Universidade M. Md Din1,4, J. Wang1,2, S. Kennedy2, S. Campbell3, A. Studer2 Federal de Santa Catarina, Florianópolis, Brazil and S. Dou11. Institute of Superconducting and Electronic Material, University of Wollongong, Wollongong, NSW, Australia; 2. Bragg Institute, Australian Nuclear Science and Technology 2:18 Organization, Lucas Heights, NSW 2234, NSW, Australia; 3. School of Physical, Environmental and Mathematical Sciences, DE-03. Development of Quantitative First Order Reversal Curve (FORC) Analysis. C.L. Dennis1, S. Lund1, R.D. Shull1, The University of New South Wales, Canberra, ACT 2600, ACT, 2 2 2 2 Australia; 4. Department of Electrical & Electronic Engineering, C. Schopphoven , P. Bender , A. Tschoepe and R. Birringer 1. Faculty of Engineering, National Defence University of Malaysia, National Institute of Standards & Technology, Gaithersburg, MD; Kem Sungai Besi, 57000, Kuala Lumpur, Malaysia 2. Universitat des Saarlandes, Saarbruecken, Germany

2:30 DE-04. Magnetism of Tb clusters on a length scale shorter than that of the exchange.S. Ghosh1, B. Sanyal2, C. van Dijk3, J. Bowlan4, L. Peters3, J. Jalink3, W. de Heer5, O. Eriksson2, M.I. Katsnelson3, A. Fielicke4 and A. Kirilyuk31. School of Applied and Engineering Physics, Cornell University, Ithaca, NY; 2. Department of Physics and Astronomy, Uppsala University, Uppsala, Sweden; 3. Institute for Molecules and Materials, Radboud University Nijmegen, Nijmegen, Netherlands; 4. Fritz- Haber-Institut der Max-Planck-Gesellschaft, Berlin, Germany; 5. School of Physics, Georgia Institute of Technology, Atlanta, GA 134 PROGRAM PROGRAM 135

2:42 3:54 DE-05. Magnetic order and fluctuations of Fe3O4 DE-11. One-dimensional zinc ferrite nano-chains synthesis by nanoparticles.K. Chesnel1, Y. Cai1, M. Trevino1, A. Westover1, chemical self-assembly assistant by magnetic field.Z. Kou1, R. Harrison3, A. Reid2 and A. Scherz21. Physics and Astronomy, W. Zhang1,2, H. Huang3, C. Ji1, J. Yue1, D. Zhang1, Y. Zhai1 and Brigham Young University, Provo, UT; 2. SSRL, SLAC, Palo Alto, H. Zhai41. Department of Physics, Southeast University, Nanjing, CA; 3. Physics and Astronomy, Brigham Young University, Provo, China; 2. MESA+ Institute for Nanotechnology, University of UT Twente, Enschede, Netherlands; 3. Department of Material Science and Engineering, Southeast University, Nanjing, China; 4. National Laboratory for Solid State Microstructures, Nanjing 2:54 University, Nanjing, China DE-06. Scanning Probe Measurements of Magnetoresistive Telegraph Noise in Magnetite Nanoparticles. S.K. Piotrowski1, S.A. Majetich1, A. Hevroni2, G. Markovich2 and E.R. Evarts31. Physics, Carnegie Mellon University, Pittsburgh, PA; 2. School of Chemistry, Tel Aviv University, Tel Aviv, Israel; 3. NIST, Boulder, WEDNESDAY GOVERNOR’S SQ 15 CO AFTERNOON 1:30 3:06 DE-07. Probing the Magnetic Behavior of Single Session DF Nanodots.A. Neumann1, D. Altwein1, C. Thönnissen1, A. Frauen1, RARE EARTH-FREE PERMANENT R. Wieser1, A. Berger2, A. Meyer3, E. Vedmedenko1 and MAGNETS I H.P. Oepen1,41. Institut für Angewandte Physik, Universität Hamburg, Hamburg, Germany; 2. CIC nanoGUNE Consolider, Ping Liu, Co-Chair San Sebastian, Spain; 3. Institut für Physikalische Chemie, Jinbo Yang, Co-Chair Universität Hamburg, Hamburg, Germany; 4. IKERBASQUE, Basque Foundation for Science, Bilbao, Spain 1:30 DF-01. Learning from Space: Characterizing Chemical Disordering 3:18 in Meteorites to Inform Laboratory Synthesis of L10 FeNi 1 2 3 DE-08. The impact of Fe decoration on magnetism and spin- Permanent Magnets. N. Bordeaux , A. Mubarok , E. Poirier , 4 2 3 1 dependent electronic properties of Co nanoislands on Cu(111). K. Barmak , J.I. Goldstein , F.E. Pinkerton and L.H. Lewis 1. M. Corbetta1, S. Phark1, J. Fischer1,2, S. Ouazi1, D. Sander1 and Chemical Engineering, Northeastern University, Boston, MA; 2. J. Kirschner11. Max-Planck-Institut für Mikrostrukturphysik, Mechanical and Industrial Engineering, University of Halle (Saale), Germany; 2. Laboratório de Filmes Finos e Massachusetts, Amherst, MA; 3. Chemical Sciences and Materials Superfícies, Departamento de Física, Universidade Federal de Systems Lab, GM R&D Center, Warren, MI; 4. Applied Physics Santa Catarina, Florianópolis, Brazil and Applied Mathematics, Columbia University, New York, NY

3:30 1:42 1,2 DE-09. Magnetic property tuning of epitaxial compositionally- DF-02. Development of MnBi permanent magnet. J. Cui , 5 6 4 4 3 modulated (Co,Mg,Ni)Fe2O4 ferrimagnetic pillars in a M. Kramer , M. Marinescu , P. Liu , V. Nguyen , Q. Huang , 1 2 7 1 1 BiFeO3 ferroelectric matrix. D. Kim1, N.M. Aimon1, X. Sun1 J. Choi , I. Takeuchi , H. Reeve , G. Li , T. Droubay , 1 1 1 and C.A. Ross11. MIT, Cambridge, MA E. Polikarpov , J. Templeton and J. Darsell 1. Energy and Environment Directorate, Pacific Northwest National Lab, Richland, WA; 2. Materials Science and Engineering, University 3:42 of Maryland, College Park, WA; 3. NIST Center for Neutron Research, National Institute of Standars and Technology, DE-10. Magnetic properties of La1–xSrxMnO3 nanoparticles prepared via molten salt synthesis. M. Kacenka1, O. Kaman2, Gaithersburg, MD; 4. Physics, University of Texas at Arlington, M. Marysko2, Z. Jirak2, S. Vratislav3 and I. Lukes11. Department Arlington, TX; 5. Materials Science and Engineering, AMES of Inorganic Chemistry, Faculty of Science, Charles University, Laboratory, AMES, IA; 6. Electron Energy Corp., Landisville, PA; Prague, Czech Republic; 2. Institute of Physics, Academy of 7. United Technologies Research Center, East Hartford, CT Sciences of the Czech Republic, Prague, Czech Republic; 3. Faculty of Nuclear Sciences and Physical Engineering, Czech 1:54 Technical University, Prague, Czech Republic DF-03. High Coercivity MnAl(C) Permanent Magnets. M.J. Lucis1, M. Wang1 and J.E. Shield11. University of Nebraska-Lincoln, Lincoln, NE 136 PROGRAM PROGRAM 137

2:06 3:18 DF-04. MnBi Particles with High Energy Density made by Spark DF-10. Phase formation and magnetic properties of B and Fe Erosion. P. Nguyen1,3, S. Jin1,3 and A.E. Berkowitz2,31. Materials modified Hf-Co alloys. M. Wang1, J. Lewis1,2, E. Folcke2, Science and Engineering, UC San Diego, La Jolla, CA; 2. F. Letellier2, J. Le Breton2 and J.E. Shield11. Mechanical and Physics, UC San Diego, La Jolla, CA; 3. Center for Magnetic Materials Engineering, University of Nebraska-Lincoln, Lincoln, Recording Research, UC San Diego, La Jolla, CA NE; 2. University of Rouen, Rouen, France

2:18 3:30

DF-05. XMCD studies on ferromagnetism in MnBi permanent DF-11. Phase Composition and Nanostructure of Zr2Co11-Based magnets. Y. Chen1, E. Goering1, A. Leineweber1, G. Schütz1, Alloys. Y. Jin1, W. Zhang1, R. Skomski1, J.E. Shield1 and H. Kronmüller1, R. Neelam2, A. Gabay2 and G. Hadjiapanayis21. D.J. Sellmyer11. Nebraska Center for Materials and Nanoscience, Schütz, Max Planck Institute for Intelligent Systems, Stuttgart, University of Nebraska, Lincoln, NE Germany; 2. Department of Physics and Astronomy, University of Delaware, Newark, DE 3:42

2:30 DF-12. Unraveling the structural mystery of Zr2Co11 compound polymorphs.X. Zhao1, M. Nguyen1, W. Zhang2, C. Wang1, DF-06. Hard magnetic properties on FeNi-based materials: The NWA M. Kramer1, D. Sellmyer2, X. Li2, F. Zhang1, L. Ke1, V. Antropov1 6259 meteorite as a model system. E. Poirier1, F.E. Pinkerton2, and K. Ho11. Ames Laboratory, Ames, IA; 2. Nebraska Center for R.C. Kubic2, R.K. Mishra2, M.P. Balogh2, N.D. Ellison2, Materials and Nanoscience and Department of Physics and A. Mubarok3, J.I. Goldstein3, K. Barmak4, N. Bordeaux5 and Astronomy, University of Nebraska, Lincoln, NE L.H. Lewis51. MEDA Engineering and Technical Services, Southfield, MI; 2. Chemical and Materials Systems Lab, General 3:54 Motors Global R&D Center, Warren, MI; 3. Department of Mechanical Engineering, University of Massachusetts, Amherst, DF-13. Development and intrinsic properties of noncubic MA; 4. Department of Applied Physics and Applied Mathematics, ferromagnetic (Zr,Ti)Fe2-based compounds. W. Zhang1, Columbia University, New-York, NY; 5. Department of Chemical R. Skomski1, J. Shield1 and D. Sellmyer11. Physics and Engineering, Northeastern University, Boston, MA Astronomy, University of Nebraska, Lincoln, NE

2:42 4:06 DF-07. Effect of Grain Size on Spinodal Decomposition and Magnetic DF-14. Combinatorial search of rare-earth-free permanent magnets: Properties in Melt-Spun Alnico Alloys. B. Frincu1, K. Löwe1, magnetic and microstructural properties of Co-Zr-B thin F. Khan3, O. Gutfleisch1,2 and G. Hadjipanayis31. Technische films. T. Gao1, S. Fackler1, L. Fang1, B. Zayac1, K. Lopez1, Universität Darmstadt, Darmstadt, Germany; 2. Fraunhofer ISC, I. Takeuchi1, M.J. Krammer2 and A. Mehta31. University of IWKS Group Materials Recycling and Resource Strategy, Hanau, Maryland, College Park, MD; 2. Ames Laboratory, Iowa State Germany; 3. Department of Physics and Astronomy, University of University, Ames,, IA; 3. Stanford Synchrotron Radiation Delaware, Newark, DE Lightsource, SLAC National Accelerator Laboratory, Menlo Park, CA 2:54 4:18 DF-08. Study on the magnetic properties of (Fe,Co)2B alloy with high magnetocrystalline anisotropy.J. Hong1,2, K. Skokov1, DF-15. Magnetism of High-Energy Rare-Earth-Free Nanocomposites. M. Kuzmin1 and O. Gutfleisch1,31. TU Darmstadt, Darmstadt, B. Balasubramanian1,2, R. Skomski1,2, B. Das1,2, X. Li1 and Germany; 2. Zhejiang University, Hangzhou, Zhejiang, China; 3. D.J. Sellmyer1,21. Nebraska Center for Materials and Materials Recycling Resource Strategy, Frauhofer ISC, Hanau, Nanoscience, University of Nebraska, Lincoln, NE; 2. Department Germany of Physics and Astronomy, University of Nebraska, Lincoln, NE

3:06 DF-09. Magnetic properties of Co-Zr-B magnets produced by spark plasma sintering method. T. Saito1 and T. Akiyama11. Chiba Institute of Technology, Chiba, Japan 138 PROGRAM PROGRAM 139

WEDNESDAY GOVERNOR’S SQ 16 3:06 AFTERNOON DG-07. Magneto-static interaction of single NiFe 1:30 nanostructures.M. Rahbar Azad1, A. Kobs1, B. Beyersdorff1, P. Staeck1, H. Spahr1, R. Frömter1 and H. Oepen11. Institut für Session DG Angewandte Physik, Hamburg, Germany SOFT MAGNETS: THIN FILM MATERIALS II Paul Ohodnicki, Chair 3:18 DG-08. High-efficiency GHz second harmonic generation from thin- 1 1:30 film Ni81Fe19 in ferromagnetic resonance. C. Cheng and W.E. Bailey11. Materials Science and Engineering, Applied DG-01. Uniaxial Anisotropy and its Manipulation in Amorphous Physics and Applied Mathematics, Columbia University, New 1,2 2 Co68Fe24Zr8 Thin Films.(Invited) Y. Fu , I. Barsukov , York, NY R. Meckenstock2, J. Lindner2, Y. Zhai1, B. Hjörvarsson3 and M. Farle21. Department of Physics, Southeast University, Nanjing, China; 2. Fakultät für Physik and Center for Nanointegration 3:30 Duisburg-Essen (CeNIDE), Universität Duisburg-Essen, DG-09. Magnetic and optical properties of various formation Ni-Au Duisburg, Germany; 3. Department of Physics and Astronomy, nanowire arrays. H. Seo1, B. An1, M. Cho1, J. Wu2 and Uppsala University, Uppsala, Sweden Y. Kim1,21. Materials Science and Engineering, Korea University, Seoul, Republic of Korea; 2. Pioneer Research Center for 2:06 Biomedical Nanocrystals, Seoul, Republic of Korea DG-02. Magnetic characterization of amorphous CoFeZr thin films grown by combinatorial sputtering. A. Frisk1, M. Ahlberg1 and 3:42 1 G. Andersson 1. Physics and Astronomy, Uppsala University, DG-10. High magnetization Fe-Co fine particles by thermal Uppsala, Sweden decomposition and hydrogen reduction. B. Cui1, M. Marinescu1 and J. Liu11. Electron Energy Corporation, Landisville, PA 2:18 DG-03. Domain wall motion in circularly magnetized cylindrical 3:54 microwire measured by magneto-optical Kerr.Y.P. Ivanov1, 1 1 1 DG-11. Magnetic properties of Y0.5Tb0.5Fe2D4.2 compound under R.P. del Real , O. Chubykalo-Fesenko and M. Vázquez 1. continuous magnetic field up to 220 kG and neutron Instituto de Ciencia de Materiales de Madrid (CSIC), Madrid, diffraction up to 130 kG.V. Paul Boncour1,2, M. Guillot1,2, Spain A. Hoser3,4 and N. Stusser3,41. Institut de Chimie des Matériaux de Paris Est, CNRS, Thiais, France; 2. LNCMI, CNRS, Grenoble, 2:30 France; 3. HZB, BENSC, Berlin, Germany; 4. BENSC, HZB,, Berlin, Germany DG-04. Microstructure and magnetic properties of Fe-Si-B-P-Cu submicron wires with small Mn additions. N. Lupu1,2, A. Makino2, S. Corodeanu1, Y. Yamada2, P. Sharma2, T. Ovari1 4:06 1 and H. Chiriac 1. Magnetic Materials and Devices, National DG-12. MEMS fabricated microtransformer with closed Fe-Co Institute of R&D for Technical Physics, Iasi, Romania; 2. magnetic core for high frequency power applications. Research and Development Center for Ultra High Efficiency D. Dinulovic1, A. Gerfer1, O. Opitz1, M. Kaiser2, M.C. Wurz2 and Nano-crystalline Soft Magnetic Materials, Tohoku University, L. Rissing21. R&D, Wuerth Elektronics eiSos, Garhing, Germany; Sendai, Japan 2. IMPT (Institute for Micro Production Technology), Leibniz Universität Hannover, Garbsen, Germany 2:42 DG-05. High-frequency magnetic properties of nanocolumnar films. 4:18 T. Eguchi1, N. Nakagawa1, M. Yonetsu1, K. Okamoto1, 1 1 DG-13. First Principles calculation of magnetic structures in iron T. Suetsuna and S. Suenaga 1. Corporate Research & sample with Cu precipitate. K. Odbadrakh1,4, R. Stoller1,2, Development Center, Toshiba Corporation, Kawasaki, Japan Y. Osetskiy1,2, D. Nicholson1,3 and G. Stocks1,21. Center for Defect Physics, ORNL, Oak Ridge, TN; 2. Materials Science and 2:54 Technology Division, ORNL, Oak Ridge, TN; 3. Computational Science and Mathematics Division, ORNL, Oak Ridge, TN; 4. DG-06. Magnetic properties of Fe films prepared from a deep eutectic Joint Institute for Computational Sciences, UT-ORNL, Oak Ridge, 1 1 1 1 solvent. T. Yanai , T. Shimokawa , Y. Watanabe , M. Nakano , TN K. Suzuki2 and H. Fukunaga11. Graduate School of Engineering, Nagasaki University, Nagasaki, Nagasaki, Japan; 2. Department of Material Engineering, Monash University, Clayton, VIC, Australia 140 PROGRAM PROGRAM 141

WEDNESDAY GOVERNOR’S SQ 12 2:42 AFTERNOON DH-07. Experimental identification of the anisotropic intrinsic 1:30 anomalous Hall effect in Fe.J. Xu1, L. Wu1, Y. Li1, D. Tian1, K. Zhu1 and X. Jin11. State Key Laboratory of Surface Physics Session DH and Department of Physics, Fudan University, Shanghai, SPIN HALL EFFECTS Shanghai, China Jing Shi, Chair 2:54

1:30 DH-08. Anomalous Hall effect arising from noncollinear antiferromagnetism: Mn3Ir as an example. H. Chen1, Q. Niu1 DH-01. Seed layer dependence of the spin-Hall-effect-induced and A.H. MacDonald11. Department of Physics, University of 1 2 switching in perpendicular CoFeB films. Y. Lau , H. Kurt , Texas at Austin, Austin, TX N. Thiyagarajah1, K. Rode1 and J. Coey11. School of Physics and CRANN, Trinity College Dublin, Dublin, Ireland; 2. Engineering Physics Department, Istanbul Medeniyet University, Istanbul, 3:06 Turkey DH-09. Magnetization reversal induced by in-plane current in Ta/CoFeB/MgO structures with perpendicular magnetic easy 1 1,2 2 2 1:42 axis. C. Zhang , M. Yamanouchi , H. Sato , S. Fukami , S. Ikeda1,2, F. Matsukura1,3 and H. Ohno1,21. Laboratory for DH-02. Spin-Hall Nano-oscillator: a micromagnetic study. Nanoelectronics and Spintronics, Research Institute of Electrical 1 2 3 1 A. Giordano , M. Carpentieri , A. Laudani , B. Azzerboni and Communication, Tohoku University, Sendai, Miyagi, Japan; 2. 1 G. Finocchio 1. Department of Electronic Engineering, Industrial Center for Spintronics Integrated Systems, Tohoku University, Chemistry and Engineering, University of Messina, Messina, Sendai, Miyagi, Japan; 3. WPI Advanced Institute for Materials Italy; 2. Department of Electrical and Information Engineering, Research, Tohoku University, Sendai, Miyagi, Japan Politecnico of Bari, Bari, Italy; 3. Department of Engineering, University of Roma, Roma, Italy 3:18

1:54 DH-10. Spin torque ferromagnetic resonance in Ta/Py, Ta/CoFe and Ta/CoFeB bilayer films. K. Kondou1, H. Sukegawa2, S. Mitani2, DH-03. Size dependence of Spin Hall Effect Spin Torque switching of A. Ganguly3, S. Kasai1,2, A. Barman3, Y. Niimi4 and Y. Otani1,41. 1 1 Perpendicularly polarized magnetic dots. D. Bhowmik , L. You RIKEN-CEMS, Wako, Japan; 2. National Institute for Materials 1 and S. Sayeef 1. University of California Berkeley, Berkeley, CA Science, Tsukuba, Japan; 3. Department of Condensed Matter Physics and Material Sciences, S. N. Bose National Centre for 2:06 Basic Sciences, Kolkata, India; 4. Institute for Solid State Physics, University of Tokyo, Kashiwa, Japan DH-04. Comparative studies of anti-damping and field-like torques generated by spin-orbit interactions in NM/FM/Oxide structures via DC, AC, and FMR techniques. C. Pai1, 3:30 1 1 2 1 L.H. Leao , M. Nguyen , D.C. Ralph and R.A. Buhrman 1. DH-11. Interface engineering of spin-orbit torque in perpendicular Applied Physics, Cornell University, Ithaca, NY; 2. Physics, magnetized Pt/CoFeB/MgO trilayers. X. Qiu1, Y. Wu1, Cornell University, Ithaca, NY K. Narayanapillai1, P. Deorani1, X. Yin2, A. Rusydi2, K. Lee3,4, H. Lee5 and H. Yang11. Department of Electrical and Computer 2:18 Engineering, National University of Singapore, Singapore, Singapore; 2. Singapore Synchrotron Light Source, National 1 1 1 DH-05. Nanowire Spin Hall Oscillator. Z. Duan , A. Smith , L. Yang , University of Singapore, Singapore, Singapore; 3. Department of 1 1 B. Youngblood and I.N. Krivorotov 1. Physics & Astronomy, UC Materials Science and Engineering, Korea University, Seoul, Irvine, Irvine, CA Republic of Korea; 4. KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul, Republic of 2:30 Korea; 5. PCTP and Department of Physics, Pohang University of Science and Technology, Kyungbuk, Republic of Korea DH-06. Anisotropic Transport and Torques Induced by Spin Hall Effect in Magnetic Bilayers. P. Gonzalez Barba1, S. Yang2, X. Wang1, S.S. Parkin2 and A. Manchon11. Physical Science and Engineering Division, King Abdullah University of Science and Technology, Thuwal, Saudi Arabia; 2. IBM Almaden Research Center, San Jose, CA 142 PROGRAM PROGRAM 143

3:42 DP-02. Study on Spin Transport Properties in Single-layer Graphene by Using Magnetization Dynamics. Z. Tang1, E. Shikoh1, DH-12. Magnetization dynamics driven by the combined effect of the H. Ago2, K. Kawahara2, Y. Ando1, T. Shinjo1 and M. Shiraishi11. Spin Transfer Torque and the Spin Orbit Torque. 1 2 3 Graduate School of Engineering Science, Osaka University, R. Tomasello , M. Carpentieri and G. Finocchio 1. Department of Toyonaka-city, Japan; 2. Institute for Material Chemistry and Computer Science, Modeling, Electronics and System Science, Engineering, Kyushu University, Fukuoka, Japan University of Calabria, Arcavacata di Rende, Cosenza, Italy; 2. Department of Electrical and Information Engineering, Politecnico of Bari, Bari, Bari, Italy; 3. Department of Electronic DP-03. Cryogenic Orthogonal Spin-Transfer Spin-Valve Magnetic Engineering, Industrial Chemistry and Engineering, University of Memory Devices. L. Ye1, L. Rehm1, T. Ohki2, I.V. Vernik3, Messina, Messina, Messina, Italy A. Kirichenko3, O. Mukhanov3 and A.D. Kent11. Department of Physics, New York University, New York, NY; 2. Raytheon BBN Technologies, Cambridge, MA; 3. HYPRES, Elmsford, NY 3:54

DH-13. Effect of the annealing temperature on the spin pumping and DP-04. Sub-10-nm Energy-efficient Magnetic Tunneling Junctions 1 spin Hall angle at the CoFeB/Ta interface. M. Jamali , with 90 nA Switching Current. J. Hong1, P. Liang2, V. Safonov4 1 1 A. Klemm and J. Wang 1. Electrical & Computer Eng., and S. Khizroev2,31. Electrical Engineering and Computer University of Minnesota, Minneapolis, MN Sciences, University of California, Berkeley, Berkeley, CA; 2. Electrical Engineering, University of California-Riverside, 4:06 Riverside, CA; 3. Electrical and Computer Engineering, Florida International University, Miami, FL; 4. Mag and Bio Dynamics, DH-14. Induced magneto-transport properties in Pd/YIG and Pt/YIG Escondido, CA bilayers.T. Lin1, C. Tang1, J. Shi1, B. Youngblood2 and I. Krivorotov21. Department of Physics and Astronomy, Univ. of California, Riverside, Riverside, CA; 2. Department of Physics DP-05. Space- and Time-Resolved Observation of Electron Spin and Astronomy, University of California at Irvine, Irvine, CA Transport in a (110) GaAs/AlGaAs Multiple Quantum Well at Room Temperature. N. Yokota1, K. Ikeda1 and H. Kawaguchi11. Graduate School of Materials Science, Nara Institute of Science 4:18 and Technology, Ikoma, Nara, Japan DH-15. XMCD and Inverse spin Hall effect investigation of the YIG/Pd interface. O. d’Allivy Kelly1, A. Anane1, V. Cros1, DP-06. Chirality and space curvature induced by interfacial spin- R. Bernard1, E. Jacquet1, C. Deranlot1, J. Ben Youssef3, orbit coupling. K. Kim1,2, H. Lee2, K. Lee3 and M.D. Stiles41. F. Wilhelm2, A. Rogalev2 and A. Fert11. Unite Mixte de Physique Basic Science Research Institute, POSTECH, Pohang, Kyungbuk, CNRS/Thales & Universite Paris-Sud 11, Palaiseau, France; 2. Republic of Korea; 2. Department of Physics, POSTECH, European Synchrotron Radiation Facility (ESRF), Grenoble, Pohang, Kyungbuk, Republic of Korea; 3. Department of France; 3. Université de Bretagne Occidentale, LMB-CNRS, Materials Science and Engineering, Korea University, Seoul, Brest, France Kyungbuk, Republic of Korea; 4. Center for Nanoscale Science and Technology, NIST, Gaithersburg, MD

DP-07. Experimental observation of anti-damping spin-orbit torques in (Ga,Mn)As. H. Kurebayashi1,2, J. Sinova3,5, D. Fang1, WEDNESDAY EXHIBIT HALL A. Irvine1, J. Wunderlich4, V. Novak5, R. Campion6, AFTERNOON B. Gallagher6, E. Vehstedt3, L. Zarbo5, K. Vyborny5, A. Ferguson1 2:30 and T. Jungwirth5,61. University of Cambridge, Cambridge, —- Please Select —-, United Kingdom; 2. PRESTO, JST, Kawaguchi, Session DP Japan; 3. Physics, Texas A&M University, College Station, TX; 4. HItachi Cambridge Laboratory, Cambridge, United Kingdom; 5. SPIN TRANSPORT Institute of Physics ASCR, Prague, Czech Republic; 6. University (Poster Session) of Nottingham, Nottingham, United Kingdom Tingyong Chen, Chair DP-08. Withdrawn DP-01. A Novel Method to Verify Spin Diffusion Length. Y. Niimi1, 1 1 1 1 1,2 D. Wei , H. Idzuchi , T. Wakamura , T. Kato and Y. Otani 1. DP-09. Spin transfer as a conservative magnetization mechanism in ISSP, University of Tokyo, Chiba, Japan; 2. RIKEN-CEMS, Wako, nanomagnets. G. Bertotti1, C. Serpico2 and I.D. Mayergoyz31. Japan INRIM, Torino, Italy; 2. Dept. of Electrical Engineering, University of Napoli Federico II, Napoli, Italy; 3. Dept. of Electrical and Computer Engineering, University of Maryland, College Park, MD 144 PROGRAM PROGRAM 145

DP-10. Field and current-induced motion of magnetic domain walls WEDNESDAY EXHIBIT HALL in (Co/Ni) nanostrips. K. Yamada1,2, J. Jamet1, Y. Nakatani2, 3 1 1 1 3 AFTERNOON K. Ueda , R. Weil , A. Mougin , A. Thiaville and T. Ono 1. 2:30 Laboratoire de Physique des Solides, University Paris Sud, Paris, France; 2. Graduate School of Informatics and Engineering, University of Electro-Communications, Chofu, Tokyo, Japan; 3. Session DQ Institute for Chemical Research, Kyoto Uiversity, Kyoto, Japan FUNDAMENTAL PROPERTIES AND COOPERATIVE PHENOMENA II: DP-11. Hybrid Magnetoresistance in the Proximity of a Ferromagnet. CORRELATED SYSTEMS S. Huang1, Y. Lu2, D. Qu1, B. Miao1,3, J. Cai2 and C. Chien11. Department of Physics and Astronomy, Johns Hopkins University, (Poster Session) Baltimore, MD; 2. Beijing National Laboratory for Condensed Jaime Fernandez-Baca, Chair Matter Physics, Institute of Physics, Chinese Academy of Sciences, Beijing, China; 3. National Laboratory of Solid State DQ-01. Magnetic hyperfine interactions on Cd sites of the CsCI-type Microstructures and Department of Physics, Nanjing University, rare-earth-cadmium compounds RCd (R = Ce, Pr, Nd, Sm, Nanjing, China Gd, Tb, Dy, Ho, Er). F.H. Cavalcante1, O. Leite2, A.W. Carbonari1, R.N. Saxena1, B. Bosch-Santos1, DP-12. Diffusive Rashba spin torque in ferromagnetic J.T. Cavalcante2, H. Saitovitch2 and M. Forker2,31. CRPq, heterostructures. C. Ortiz Pauyac1, X. Wang1, M. Chshiev2 and IPEN/USP, São Paulo, São Paulo/SP, Brazil; 2. EXP, CBPF, Rio A. Manchon11. King Abdullah of Science and Technology, de Janeiro, RJ, Brazil; 3. Helmholtz Institut für Strahlen-und Thuwal, Saudi Arabia; 2. SPINTEC, UMR-8191, Kernphysik, Universität Bonn, Bonn, Germany CEA/CNRS/UJF/GINP, INAC, Grenoble, France DQ-02. The effect of Au and Ni doping on the heavy fermion state of DP-13. Current dependence of spin torque switching rate based on the Kondo lattice antiferromagnet CePtZn. S.K. Dhar1, Fokker-Planck approach. T. Taniguchi1 and H. Imamura11. Y. Aoki2, A. Provino3,4 and P. Manfrinetti3,41. Condensed Matter Spintronics Research Center, AIST, Tsukuba, Ibaraki, Japan Physics & Materials Science, Tata Institute of Fundamental Research, Mumbai, Maharashtra, India; 2. Department of Physics, Tokyo Metropolitan University, Tokyo, Japan; 3. DP-14. (Filed, current) phase diagrams of in-plane STTRAM cells Departimento Di Chimica e Chimica Industriale, Universita di with low effective magnetization storage layers.L. San Genova, Genova, Italy; 4. Institute SPIN-CNR, Genova, Italy Emeterio Alvarez1, B. Lacoste1, B. Rodmacq1, L.E. Nistor2, M. Pakala3, R.C. Sousa1 and B. Dieny11. SPINTEC, UMR(8191) CEA/CNRS/UJF/Grenoble INP, Grenoble, France; 2. Applied DQ-03. Low temperature crystal structure and magnetic properties of 1 1 1,2 Materials SGG CTO, Meylan, France; 3. Applied Materials SGG RAl2 A. Pathak , D. Paudyal , K.A. Gschneidner, Jr. and CTO, Sunnyvale, CA V.K. Pecharsky1,21. The Ames Laboratory, USDOE, Iowa State University, Ames, IA; 2. Department of Materials Science and Engineering, Iowa State University, Ames, IA DP-15. Temperature dependence of the switching field distributions in all-perpendicular spin-valve nanopillars. D.B. Gopman1, D. Bedau4, S. Mangin2,3, E.E. Fullerton3, J.A. Katine4 and DQ-04. Valence fluctuations in CeCo2 and Ti-doped CeCo2. Y.- A.D. Kent11. Physics, New York University, New York, NY; 2. . Oner11. Dept. of Physics, Istanbul technical University, Istanbul, Institute Jean Lamour, UMR CNRS 7198, Université de Lorraine, Turkey Vandoeuvre, France; 3. CMRR, University of California at San Diego, La Jolla, CA; 4. HGST San Jose Research Center, San DQ-05. The low density phase diagram of Yterbium atoms confined in Jose, CA an optical superlattice. J. Silva Valencia1, R. Franco1 and M. Figueira21. Physics, Universidad Nacional de Colombia, DP-16. Seebeck coefficient of ferromagnetic thin films near room Bogotá, Colombia; 2. Universidade Federal Fluminense, Niteroi, temperature. S.J. Mason1, A.D. Avery1, D. Bassett1, Rio de Janeiro, Brazil D. Wesenberg1 and B.L. Zink11. Physics and Astronomy, University of Denver, Denver, CO DQ-06. Antiferromagnetic ordering in NdAuGe compound.A.K. Bashir1, M.B. Tchoula Tchokonte1, J. Snyman2, B.M. Sondezi2 and A.M. Strydom21. Physics, University of the Western cape, Bellville, Western Cape, South Africa; 2. Physics, University ofJohannesburg, Auckland Park, Johannesburg, South Africa

DQ-07. Magnetic behavior characterization of LaMn2 (Si(1-x) Gex)2 compounds through magnetic hyperfine field measurements. B. Bosch-Santos1, A.W. Carbonari1, G.A. Cabrera-Pasca1 and R.N. Saxena11. CRPq, IPEN/USP, Sao Paulo, Sao Paulo, Brazil 146 PROGRAM PROGRAM 147

DQ-08. Magnetocapacitance in CdCr1.8In0.2S4 Single Crystal DQ-14. A study of spin canting in Li3Fe2(PO4)3 with Mössbauer Annealed in Cadmium Vapor.Y. Xie1, Z. Yang1, Z. Zhang1, spectroscopy under 5 T. H. Kim1, T. Kouh1 and C. Kim11. Z. Huang1, B. Yuan1, J. Chen1, W. Song1, Y. Sun1, S. Zhou2 and Department of Physics, Kookmin University, Seoul, Republic of Y. Zhang31. Institute of Solid State Physics, Chinese Academy of Korea Sciences, Hefei, China; 2. Institute of Ion Beam Physics and Materials Research, Helmholtz-Zentrum Dresden-Rossendorf, DQ-15. Domain Nucleation Array and its Interaction with Magnetic Dresden, Germany; 3. High Magnetic Field Laboratory, Chinese Nanoparticles. T. Klein1, Y. Feng1, L. Yu2, Y. Wang1 and Academy of Sciences, Hefei, China J. Wang11. University of Minnesota, Minneapolis, MN; 2. University of Science and Technology of Beijing, Beijing, China 1,2 DQ-09. In situ X-ray powder diffraction study of Ho5Ge4 N.K. Singh , Y. Mudryk1, V.K. Pecharsky1,3 and K.A. Gschneidner, Jr.1,31. The Ames Laboratory, U.S. Department of Energy, Iowa State University, Ames, IA; 2. Aldrich Materials Science, Sigma Aldrich Corp., Milwaukee, WI; 3. Department of Materials Science and WEDNESDAY EXHIBIT HALL Engineering, Iowa State University, Ames, IA AFTERNOON 2:30

DQ-10. Evolution of the magnetic properties along the RCuBi2 (R = Ce, Pr, Nd, Gd, Sm) series of intermetallic compounds. Session DR C.R. Jesus1, M.M. Piva1, P.S. Rosa1 and P.G. Pagliuso11. Instituto de Física “Gleb Wataghin”, Universidade Estadual de Campinas, MICROSTRUCTURES FOR MICROWAVE Campinas, São Paulo, Brazil APPLICATIONS (Poster Session) DQ-11. Thermal neutron diffraction determination of the magnetic Jaejin Lee, Chair 1 3 structure of EuCu2Ge2W.N. Rowan-Weetaluktuk , P. Lemoine , J.M. Cadogan2 and D. Ryan11. Physics, McGill University, Montreal, QC, Canada; 2. School of Physical, Environmental and DR-01. Microwave absorbing properties of hollow microspheres 1 1 Mathematical Sciences, UNSW Canberra at the Australian coated with magnetic metal films.S. Kim and S. Kim 1. Defence Force Academy, Canberra, ACT, Australia; 3. Institut Department of Materials Engineering, Chungbuk National Jean Lamour, dept P2M,, Universite de Lorraine, Faculte des University, Cheongju, Republic of Korea Sciences et Technologies, Vandoeuvre-les-Nancy, France DR-02. Synthesis and characterization of iron/wüstite core/shell DQ-12. The effects of interfacial octahedral coupling on magnetic nanoparticles for magnetic hyperthermia 1 1 2 1 properties in ultrathin manganite films. E. Moon1, B. Kirby2, applications.S. Batista , M. Morales , F. Bohn , S. de Medeiros 3 D. Keavney3, P. Balachandran1, R. Sichel-Tissot1, C. Schlepütz1, and E. Baggio-Saitovitch 1. DFTE, Universidade Federal do Rio E. Karapetrova1, X. Cheng4, J. Rondinelli1 and S. May11. Grande do Norte, Natal, Rio Grande do Norte, Brazil; 2. EC&T, Department of Materials Science & Engineering, Drexel Universidade Federal do Rio Grande do Norte, Natal, Rio University, Philadelphia, PA; 2. Center for Neutron Research, Grande do Norte, Brazil; 3. Centro Brasileiro de Pesquisas National Institute of Standards and Technology, Gaithersburg, Fisicas, Rio de Janeiro, Rio de Janeiro, Brazil MD; 3. Advanced Photon Source, Argonne National Laboratory, Argonne, IL; 4. Department of Physics, Bryn Mawr College, Bryn DR-03. Core/shell/shell-structured nickel/carbon/polyaniline Mawr, PA nanocapsules with strong absorption in the S–Ku bands of microwaves.X. Liu1, S. Or1 and C. Leung11. Electrical DQ-13. Magnetism and crystal structure evolution as a function of Engineering, The Hong Kong Polytechnic University, Kowloon, temperature and doping of a new mixed valence perovskite Hong Kong system. R.L. Serrano1, U.F. Kaneko2, E. Granado2, A.F. García- 2 1 2,3 4 Flores , P. Marques-Ferreira , F.A. García , M. Nespolo and DR-04. Preparation and electromagnetic properties of 5 J.G. Duque 1. Instituto de Física, Universidade Federal de Fe(CO)5/Al2O3 core-shell structure powders by Uberlândia, Uberlândia, Minas Gerais, Brazil; 2. Instituto de mechanofusion method. C. Peng1, P. Chen1, C. Chang2, C. Wei2, Fisica ‘Gleb Wataghin’, Universidade Estadual de Campinas, C. Peng2 and R. Yang31. Department of Chemical and Materials Campinas, São Paulo, Brazil; 3. Max Planck Institute for Engineering, Ming Hsin University of Science and Technology, Chemical Physics of Solids, Dresden, Germany; 4. Faculté des Hsinchu, Taiwan; 2. Chemical Systems Research Division, Sciences et Technologies, Institut Jean Barriol, Université de Chung-Shan Institute of Science & Technology, TaoYuan, Taiwan; Lorraine, Nancy, Lorraine, France; 5. Núcleo de Física,, Campus 3. Department of Aerospace and Systems Engineering, Feng Chia Itabaiana, Universidade Federal de Sergipe, Aracajú, Sergipe, University, TaiChung, Taiwan Brazil 148 PROGRAM PROGRAM 149

DR-05. High-frequency magnetic permeability and dielectric DR-13. Disorder-modulated microwave absorption properties of permittivity of cobalt nanoparticle assemblies.V.K. Sakharov1, carbon coated FeCo nanocapsules.J. Jiang1, X. Li1, Z. Han1, R.A. Booth2 and S.A. Majetich21. Kotelnikov SBIRE RAS, Saratov, D. Li1, D. Geng1, S. Ma1, W. Liu1 and Z. Zhang11. institute of Russian Federation; 2. Physics Department, Carnegie-Mellon metal research, Shenyang, Liaoning, China University, Pittsburgh, PA DR-14. Microwave Electromagnetic and Absorption Properties of DR-06. High Performance Slow wave Elements enabled with Nano Magnetite Hollow Nanostructures. Y. Yang 1, Y. Yang1 and Patterned Permalloy Thin Film. B. Rahman1, R. Divan2, J. Ding11. Department of Materials Science and Engineering, D. Rosenman2, Y. Peng1, X. Wang1, H. Zhang3 and G. Wang11. National University of Singapore,, Singapore, Singapore Electrical Engineering, University of South Carolina, Columbia, SC; 2. Center for Nanoscale Materials, Argonne National DR-15. Numerical analysis of dominant loss parameters of ferrite thin Laboratory, Lemont, IL; 3. Intel Corporations, Columbia, SC films for conduction noise absorption in microstrip lines.G. Yoo1 and S. Kim11. Department of Materials DR-07. New Opportunities in Microwave Electronics with Engineering, Chungbuk National University, Cheongju, Republic Ferromagnetic Nanowires. M. Sharma1, B.K. Kuanr2, of Korea M. Sharma1 and A. Basu11. Centre for Applied Research in electronics, Indian Institute of Technology Delhi, New Delhi, Delhi, India; 2. Department of Physics, University of Colorado Springs, Colorado Springs, CO WEDNESDAY EXHIBIT HALL DR-08. Performance Enhanced Electrically Tunable Miniaturized AFTERNOON Patch Antenna with Thin Permalloy Film. Y. Peng1, 2:30 F. Rahman1, X. Wang1 and G. Wang11. Electrical Engineering, University of South Carolina, Columbia, SC Session DS MAGNETOELECTRIC STRUCTURES AND DR-09. A Near-Zero Index Magnetic Metamaterial Lens for Directive Radiation. F. Meng1,2, Y. Lv1, Q. Wu1 and L. Sun21. School of PHENOMENA Electronic and Information Engineering, Harbin Institute of (Poster Session) Technology, Harbin, China; 2. School of Electrical Engineering John Burton, Chair and Automation, Harbin Institute of Technology, Harbin, China

DS-01. Electric-field effects around the Skyrmion phase in the DR-10. Microwave power absorption of magnetic composites filled magnetoelectric compound Cu2OSeO3. A. Alahgholipour 1 1 1 with surface coated Fe-Al-Si flakes. K. Kim , J. Lee , J. Kim , Omrani1, J. White2, K. Prsa1, I. Zivkovic3, H. Berger4, A. Magrez4 2 2 S. Cho and S. Yoon 1. Physics, Yeungnam University, and H. Ronnow11. Pysics, EPFL, Lausanne, Vuad, Switzerland; 2. Gyeongsan, Republic of Korea; 2. R&D Center, Munmoo Co., Paul Scherrer Institut, Villigen,, Switzerland; 3. Institute of Kwangju, Republic of Korea Physics,Bijenicka, Zagreb, Croatia; 4. Crystal Growth Facility, EPFL, Lausanne, Vuad, Switzerland DR-11. Permittivity and permeability of Zn(Fe) nanoparticles and their microwave absorption in the 2–18 GHz DS-02. Effects of intrinsic magnetostrictive property on tube- 1 1 1 1 range.W. Zhenhua , J. Linwen , G. Dianyu , M. Song , topology magnetoelectric sensors with high magnetic field 1 2 2 1 J. Jingjing , A. Jing , H. Jun and Z. Zhidong 1. Shenyang sensitivity. S.M. Gillette1, Y. Chen1, O. Obi1, T. Fitchorov1, National Laboratory for Materials Science,, Institute of Metal L. Jiang2, H. Hao2, S. Wu2 and V.G. Harris11. Center for Research and International Center for Materials Physics, Chinese Microwave Magnetic Materials and Integrated Circuits, Academy of Sciences, Shenyang, 110016, China; 2. Division of Electrical and Computer Engineering Dept., Northeastern Functional Material Research, Central Iron & Steel Research University, Boston, MA; 2. Baotou Research Institute of Rare Institute, Beijing, 100081, China Earths, Baotou, Inner Mongolia, China

DR-12. Adjustment method for the indoor electromagnetic wave DS-03. Magnetoelectric effects in perovskite metal-organic 1 absorber using magnetic fluid based magnetic wood. H. Oka , frameworks. Y. Sun1, Y. Tian1, W. Wang1, L. Yan1, Y. Chai1, 1 1 2 3 4 A. Ito , K. Kubota , N. Sekino , Y. Namizaki and F.P. Dawson 1. S. Wang1 and X. Han11. State Key Laboratory of Magnetism, Electric and Electronic Engineering, Iwate University, Morioka, Institute of Physics, Chinese Academy of Sciences, Beijing, China Japan; 2. Faculty of Agriculture Environmental Sciences, Iwate University, Morioka, Japan; 3. Iwate Industrial Research Institute, Morioka, Japan; 4. Faculty of Applied Science and DS-04. Dielectric anomalies and magnetoelectric phase-existence Engineering, University of Toronto, Toronto, ON, Canada phenomenon due to spin-chains in Ca3Co2O6 E.V. Sampathkumaran1, T. Basu1, K.K. Iyer1 and K. Singh11. Tata Institute of Fundamental Research, Mumbai, India 150 PROGRAM PROGRAM 151

DS-05. Electric field driven magnetism in Pt monotomic wire on DS-13. Resonance direct and converse magnetoelectric effect in Pt(111) surface.T.H. Rana1,3, A. Kashyap2 and R. Sabirianov31. laminate composites. G. Wu1,2, T. Nan2, R. Zhang1,3, N. Zhang3 Department of Physics, The LNM Institute of Information and N. Sun21. Department of applied physics, Nanjing University Technology, Jaipur, Rajasthan, India; 2. School of Basic Sciences, of Technology, Nanjing, Jiangsu, China; 2. Electrical and Indian Institute of Technology, Mandi, Himachal pradesh, India; Computer Engineering Department, Northeastern University, 3. Departement of Physics, University of Nebraska at Omaha, Boston, MA; 3. Magnetoelectronic Lab, Nanjing Normal Omaha, NE University, Najing, Jiangsu, China

DS-06. Magnetic and magneto-electric properties of Cr2O3/ DS-14. Strain modification of magnetization using the structural 1 1 LiNbO3/Cr2O3 epitaxial multi-layer. T. Yokota , K. Ichikawa transitions of the ferroelectric BaTiO3 sandwich-layer in high- 1 and M. Gomi 1. Materials Science and Engineering, Graduate quality epitaxial CoFe2O4/BaTiO3/La0.7Sr0.3MnO3 multiferroic School of Nagoya Institute of Technology, Nagoya, Aichi, Japan heterostructures grown using the dual-laser ablation technique. D. Mukherjee1, M. Hordagoda1, M. Phan1, H. Srikanth1, S. Witanachchi1 and P. Mukherjee11. Department of DS-07. Magnetoelectric effect in zigzag chains of Fe and Fe-Pt on Physics and Center for Integrated Functional Materials (CIFM), Pt(001). P. Manchanda1, R. Skomski2, A. Prabhakar3 and University of South Florida, Tampa, FL A. Kashyap11. School of Basic Sciences, Indian Institute of Technology, Mandi, himchal pradesh, India; 2. Department of Physics and Astronomy and Nebraska Center for Materials and DS-15. Strong magnetoelectric coupling in FeGaB/PSZT Nanoscience, University of Nebraska, Lincoln, NE; 3. Department magnetoelectric/antiferroelectric heterostructures during of Electrical Engineering, IIT Madras, Madras, Tamilnadu, India antiferroelectric-ferroelectric phase transition.Z. Zhou1, X. Zhang2, T. Xie2, P. Qiu3, X. He3, T. Nan1, N.X. Sun1 and D. Sun1,21. Department of Electrical and Computer Engineering, DS-08. The converse magnetoelectric characteristics of Mn and Mg Northeastern University, Boston, MA; 2. Department of doped CoFe O –PbTiO composites.L. Ting-ting1, Z. Wang1, 2 4 3 Chemistry, Shanghai Normal University, Shanghai, China; 3. M. Jun1, C. Ning-ning1 and N. Li-jun11. Tianjin University, Shanghai Institute of Ceramics, Chinese Academy of Sciences, Tianjin, Tianjin, China Shanghai, China

DS-09. Dynamic magnetostrictive properties of magnetization-graded ferromagnetic material and application in magnetoelectric composite.C. Lu1, P. Li 1, Y. Wen1, A. Yang1, J. Yang1, W. He1, J. Zhang1, D. Wang1 and W. Li11. College of Optoelectronic WEDNESDAY EXHIBIT HALL Engineering,Chongqing University, Chongqing, China AFTERNOON 2:30 DS-10. Mechanical and Structural Properties of BTO/LSMO on STO and LAO grown using Plasma Enhanced PLD. S.L. Fletcher1, Session DT B. Walker1, C. Gonder1, R.M. Mundle1, M. Bahoura1, Q. Yang1, B. Xiao1 and A.K. Pradhan11. Center for Materials Research, CONTINUOUS GRANULAR MEDIA FOR Norfolk State University, Norfolk, VA MAGNETIC RECORDING (Poster Session) DS-11. Large E-field tunability of ferromagnetic resonance frequency Mojtaba Ranjbar, Chair in Fe59.3Co28.0Hf12.7/PZN-PT multiferroic composites. S. Li1,2, H. Du1, Q. Xue1, X. Gao1, Y. Zhang1, W. Shao1, T. Nan3, Z. Zhou3 and N. Sun31. College of Physics Science, Qingdao DT-01. Effects of sub-domain structure on initial magnetization curve 1 University, Qingdao, Shandong, China; 2. National Laboratory of and domain size distribution of stacked media. S. Sato , 1 1 Solid State Microstructures, Nanjing University, Nanjing, China; S. Kumagai and R. Sugita 1. Media and Telecommunications 3. Electrical and Computer Engineering Department, Engineering, Ibaraki university, Hitachi, Ibaraki, Japan Northeastern University, Boston, MA DT-02. Micromagnetic study on influence of recording field direction 1 1 DS-12. Electromagnetic properties of Fe-Si-Al /BaTiO3/ Nd2Fe14B on transition noise of stacked media. S. Kumagai , S. Sato and 1 particulate composites at microwave frequencies. X. Wang1, R. Sugita 1. Media and Telecommunications Engineering, Ibaraki X. Xu1, W. Gong2, Z. Feng1 and R. Gong11. School of Optical and University, Hitachi, Ibaraki, Japan Electronic Information, Huazhong University of Science and Technology, Wuhan, Hubei, China; 2. Department of Chemistry, DT-03. Investigation on graded L10-FePt(001) magnetic media grown The University of Iowa, Iowa City, IA by graded working pressures. Y. Lin1, J. Hsu2, P. Saravanan2 and P.C. Kuo11. Graduate Institute of Materials Science & Engineering, National Taiwan University, Taipei, Taiwan; 2. Physics, National Taiwan University, Taipei, Taiwan 152 PROGRAM PROGRAM 153

DT-04. Improved switchability in composite perpendicular recording DT-13. Effect of microstructure on thermal properties of FePt. media by interfacial tuning of the anisotropy gradient. A. Chernyshov1, D. Treves1, T. Le1, F. Zong1, A. Ajan1 and K. Srinivasan1, E. Roddick1 and M. Desai11. Western Digital, San R. Acharya11. Western Digital, San Jose, CA Jose, CA

DT-14. Grain segregation and uniaxial magnetic anisotropy for L10 DT-05. Multi-segregant of granular L10 FePt:(B,C). J. Chiu1, W. Wen1, type FePt-X (X=SiC, TiC) films on FePt-C template. L. Wang1, D. Wang1, K. Chang2 and C. Lai11. Material H. Kataoka1,2, H. Kikuchi1,2, A. Furuta1,2, K. Tsumura1, Engineering, National Tsing Hua University, Hsinchu, Taiwan; 2. N. Kikuchi3, S. Okamoto3, O. Kitakami3 and T. Shimatsu1,41. Seagate Technology, Fremont, CA FRIS, Tohoku University, Sendai, Japan; 2. Fuji Electric Co., Ltd., Tokyo, Japan; 3. IMRAM, Tohoku University, Sendai, Japan; 4. RIEC, Tohoku University, Sendai, Japan DT-06. On the Magnetic Performance of Vertically Graded

Anisotropy L10-FePt Films Processed by Gradient Temperature, Composition and Working Pressure. Y. Lin1, DT-15. Magnetic anisotropy and order structure of (001) textured 2,3 1 2 S. Padmanapan , P. Kuo and J. Hsu 1. Department of Materials L10-FePt polycrystalline films deposited on MgO seed layers. Science and Engineering, National Taiwan University, Taipei, A. Hotta1, T. Ono1,2, M. Hatayama1, K. Tsumura1, N. Kikuchi3, Taiwan; 2. Department of Physics, National Taiwan University, S. Okamoto3, O. Kitakami3 and T. Shimatsu1,41. FRIS, Tohoku Taipei, Taiwan; 3. Defence Metallurgical Research Laboratory, University, Sendai, Japan; 2. Fuji Electric Co. Ltd., Tokyo, Japan; Hyderabad, India 3. IMRAM, Tohoku University, Sendai, Japan; 4. RIEC, Tohoku University, Sendai, Japan DT-07. Change in magnetic and structural properties of FeRh thin films by energetic cluster ion beam irradiation. T. Koide1, DT-16. Repairing Embedded Mask Patterning Induced Crystalline Y. Saitoh2, M. Sakamaki3, K. Amemiya3, A. Iwase1 and Damage to FePt for Heat Assisted Magnetic Recording Media. T. Matsui41. Materials Science, Osaka Prefecture University, P. Quarterman1, H. Wang1 and J. Wang11. Electrical Engineering, Sakai, Japan; 2. Japan Atomic Energy Agency, Takasaki, Japan; University of Minnesota, Minneapolis, MN 3. High Energy Accelerator Research Organization, Tsukuba, Japan; 4. Research Organization for the 21st Century, Osaka Prefecture University, Sakai, Japan

DT-08. MoC Intermediate Layer for FePt Magnetic Recording WEDNESDAY EXHIBIT HALL Media. J. Tsai1, Q. Luo1, P. Chen1 and Y. Chen11. Department of AFTERNOON materials Science and engineering, National Chung Hsing 2:30 University, Taichung, Taiwan Session DU

DT-09. Orientation-controlled nonepitaxial L10 FePt thin IMAGING AND NOVEL APPROACHES films.H. Dang1, L. Liu1, L. Hao1, T. Jin1, M. Liu1, J. Cao1, Y. Wang1, J. Bai1, F. Wei1 and D. Wei21. Key Laboratory for (Poster Session) Magnetism and Magnetic Materials of the Ministry of Education, Thomas Hayward, Chair Lanzhou University, Lanzhou, Gansu, China; 2. Key laboratory for Advanced Materials Ministry of Education, Tsinghua DU-01. Microwave pump-probe transmission x-ray microscopy for University, Beijing, Beijing, China magnetization dynamics imaging.S. Bonnetti2, R. Kukreja2, H. Ohldag1, R. Houanche3, J. Pinto1, J. Frisch1, J. Stoehr1 and H. Duerr11. SLAC National Accelerator Laboratory, Menlo Park, DT-10. Enhance the Coercivity of the rhombohedral lattice L11 CoPt Thin Film.A. Sun1, S. Huang1 and C. Huang11. Department of CA; 2. Stanford University, Stanford, CA; 3. University at Albany, Chemical Engineering & Materials Science, Yuan Ze University, Albany, NY Taoyuan, Taiwan DU-02. Measurement of the GHz Range Magnetic Field Distribution DT-11. Magneto-optical properties of nanometer crystal BiAlDyIG Near a Coplanar Waveguide Using a Beating Field-Type 1 1 1 2 thin film post-treated by rapid recurrent thermal annealing MFM. Y. Endo , M. Fukushima , K. Arai , K. Yanagi , 1 1,2 (RRTA) method. Q. Yang1, Q. Wen1 and H. Zhang11. University Y. Shimada and M. Yamaguchi 1. Department of Electrical of Electronic Science and Technology of China, Chengdu, China Engineering, Graduate School of Engineering, Tohoku University, Sendai, Miyagi, Japan; 2. NICHe, Tohoku University, Sendai, Miyagi, Japan DT-12. A multi-functional testing instrument for HAMR media. H. Yang1, Y. Chen1, S. Leong1, C. An1, K. Ye1, M. Yin2 and J. Hu11. DST, Data Storage Institute, Singapore, Singapore; 2. DU-03. Phase resolved imaging of spin-wave eigenmodes in Industrial and Systems Engineering, National University of submicron ellipses using scanning transmission x-ray 1 1 Singapore, Singapore, Singapore microscopy. C. Cheng and W.E. Bailey 1. Columbia University, New York, NY 154 PROGRAM PROGRAM 155

DU-04. Evaluation of Magnetic Flux Distribution from Magnetic DU-11. Room-temperature domain reversal on the perpendicular Domains in [Co/Pd] Nanowires by nano-MDS Method using magnetic domain of hydrogen-mediated ZnCoO Contact-scanning of TMR Sensor. Y. Miyamoto1, M. Okuda1, microstructures. W. Kim1, S. Lee1, B. Kim1, J. Park1, Y. Cho2, E. Miyashita1 and N. Hayashi11. Science & Technology Research K. He3, I. Takeuchi3 and S. Jeong11. Department of Cogno- Labs., NHK (Japan Broadcasting Corporation), Tokyo, Japan Mechatronics Engineering, Pusan National University, Miryang, Republic of Korea; 2. Crystal Bank Institute, Pusan National University, Miryang, Republic of Korea; 3. Department of DU-05. The effects of nanoscale chemical inhomogeneity on the Materials Science and Engineering, University of Maryland, magnetic properties of rare earth–transition metal alloys. College Park, MD A. Reid1, C. Graves1, T. Wang1, T. Liu1, B. Wu1, A. Scherz2, A. Tsukamoto4, J. Stohr1, T. Rasing3 and H. Durr11. SLAC National Accelerator Laboratory, Menlo Park, CA; 2. European DU-12. Excitation of Vortex Translational Mode using Surface XFEL, Hamburg, Germany; 3. Radboud University Nijmegen, Acoustic Waves.S. Jain1, S. Lendinez1,2, V. Novosad1, Nijmegen, Netherlands; 4. Nihon University, Chiba, Japan J. Pearson1, F.Y. Fradin1, J. Tejada2 and S.D. Bader11. Material Science Division, Argonne National Laboratory, Argonne, IL; 2. Fisica Fonamental, Facultat de Fisica, Universitat de Barcelona, DU-06. Quantitative magnetic imaging of ultrathin wires using a Barcelona, Spain scanning NV-center microscope. J. Tetienne1,2, T. Hingant1,2, S. Rohart3, A. Thiaville3, L. Herrera Diez4, K. Garcia4, J. Kim4, D. Ravelosona4, E. Jué5, O. Boulle5, I. Miron5, G. Gaudin5, DU-13. Vortex-Antivortex in Nb based Superconductor/Ferromagnet J. Roch1 and V. Jacques1,21. LAC, Univ. Paris-Sud, ENS Cachan hybrids. A.M. Cucolo1,2, C. Di Giorgio1, F. Bobba1,2, and CNRS, Orsay, France; 2. LPQM, ENS Cachan and CNRS, A. Scarfato1,2, M. Iavarone3,4, G. Karapetrov3, V. Novosad3 and Cachan, France; 3. LPS, Univ. Paris-Sud and CNRS, Orsay, V. Yefremenko31. Department of Physics “E.R. Caianiello”, France; 4. IEF, Univ. Paris-Sud and CNRS, Orsay, France; 5. University of Salerno, Salerno, Sa, Italy; 2. SPIN CNR, CNR, Spintec, CEA, CNRS, Univ. Joseph Fourier and GINP, Grenoble, Salerno, Sa, Italy; 3. Materials Science Division, Argonne France National Laboratory, Argonne, IL; 4. Physics Department, Temple University, Philadelphia, PA DU-07. Investigations of Stacking faults in perpendicular recording media using magnetic force microscopy. S.N. Piramanayagam1, DU-14. Reverse Monte Carlo analysis for magnetic domain structure. B. Varghese1, H. Tan1 and W. Lee11. A*STAR (Agency for Science M. Tokii1, E. Kita1, C. Mitsumata2, K. Ono3, H. Yanagihara1 and Technology and Research), Data Storage Institute, Singapore, M. Matsumoto11. Univ. of Tsukuba, Tsukuba, Japan; 2. National Singapore Institute for Materials Science, Tsukuba, Japan; 3. High Energy Accelerator Research Organaization, Tsukuba, Japan DU-08. Pd/Co and Co/Ni Multilayers with PMA for Spintronic Device Applications. L. Tryputen1, A. Nguyen2, S. Chung2,3, DU-15. Addressing a domain wall depinning process in dumbbell J. Åkerman2,3, F. Guo4, R.D. McMichael4 and C.A. Ross11. shaped pemalloy magnetic nanowire.T. Chen1, C. Kuo1, Department of Materials Science and Engineering, Massachusetts A. Mishra1, C. Lee2, C. Chang3 and J. Wu11. National Changhua Institute of Technology, Cambridge, MA; 2. Material Physics, University of Education, Changhua, Taiwan; 2. National Yunlin School of Information and Communication Technology, KTH University of Science & Technology, Yunlin, Taiwan; 3. National Royal Institute of Technology, Kista, Sweden; 3. Department of Taiwan University, Taipei, Taiwan Physics, University of Gothenburg, Gothenburg, Sweden; 4. Center for Nanoscale Science and Technology, National Institute DU-16. Simulation of water diffusion effects on the NMR signal from of Standards and Technology, Gaithersburg, MD magnetic particle contrast agents. Y. Nakashima1,2 and J. Moreland11. NIST, Boulder, CO; 2. Kyushu University, DU-09. Analysis of the topological Hall conductivity in finite-sized Fukuoka, Japan magnetic elements with vortex and skyrmionic textures. M.B. Jalil1 and S. Tan2,11. Information Storage Materials Laboratory, Electrical and Computer Engineering Department, National Univ Singapore, Singapore, Singapore; 2. Data Storage Institute, Singapore, Singapore

DU-10. Magneto-thermopower of permalloy nanowires and multilayered Co/Cu microwires in lateral thermal gradients. P. Krzysteczko1, X. Hu1, N. Liebing1, K. Rott2, G. Reiss2 and H.W. Schumacher11. Physikalisch-Technische Bundesanstalt, Braunschweig, Germany; 2. Bielefeld University, Bielefeld, Germany 156 PROGRAM PROGRAM 157

WEDNESDAY EXHIBIT HALL DV-07. Magnetic properties of Sm-Co/α-Fe nanocomposite multi- layered thick film-magnets at room and high AFTERNOON 1 1 1 1 2:30 temperatures.H. Fukunaga , A. Tou , T. Morimura , M. Nakano and T. Yanai11. Nagasaki University, Nagasaki, Japan Session DV DV-08. Sm(Co1-xNix)5 ordered alloy thin films formed on Cr(100) INTERMETALLICS AND OTHER HARD single-crystal substrates. T. Yanagawa1, Y. Hotta1, M. Yamada1, MAGNETIC MATERIALS II M. Ohtake1, F. Kirino2 and M. Futamoto11. Faculty of Science (Poster Session) and Engineering, Chuo University, Tokyo, Japan; 2. Graduate School of Fine Arts, Tokyo University of the Arts, Tokyo, Japan David Parker, Co-Chair Junichiro Inoue, Co-Chair ε DV-09. Study of -Fe2O3 nanomagnets exhibiting huge coercivity and high-frequency millimeter wave absorption. S. Ohkoshi1,21. The DV-01. Influence of stoichiometry on crystal structure and magnetic University of Tokyo, Tokyo, Japan; 2. CREST, JST, Tokyo, Japan properties of epitaxial (001) Fe-Pd films on MgO single crystal.Y. Chang1,2, S. Hsiao2, S. Liu3, S. Chen3, J. Duh1 and γ H. Lee21. Materials science and Engineering, National Tsing Hua DV-10. Strucutral and magnetic properties of core-shell NiFe2O4@ - Fe2O3 nanoparticles. H.P. Chaves1, F.L. Paula1, J.A. Gomes1, University, Hsinchu, Taiwan; 2. National Synchrotron Radiation 1 1 2 3 Research Center, Hsinchu, Taiwan; 3. Materials science and J. Depeyrot , F.A. Tourinho , R. Perzynski and B. Jeyadevan 1. Engineering, Feng Chia University, Taichung, Taiwan Complex Fluids Group, Universidade de Brasília, Brasília, Brasília, Brazil; 2. PECSA, Université Pierre et Marie Curie, Paris, France; 3. Tohoku University, Sendai, Japan DV-02. Post magnetic field annealing effect on magnetic and structural properties of CoPt nanowires and nanotubes fabricated by electrochemical method. S.S. Ali1,2, G.J. Zhai1, DV-11. Morphological and magnetic properties of K. Javed2, D. Shi2, J. Jiang2 and X.F. Han21. National Space V2O5/Sm0.2CoFe1.8O4 nanocomposites processed through two step synthesis. S.E. Shirsath1, R.H. Kadam2, V.S. Shinde3, Science Center, Chinese Academy of Sciences, Beijing, China; 2. 1 1 Institute of Physics, Chinese Academy of Sciences, Beijing, China X. Liu and A. Morisako 1. Department of Information Engineering, Shinshu University, Nagano, Nagano, Japan; 2. Department of Physics, Shree Krishna Mahavidyalaya, DV-03. Exchange interaction effects on magnetic properties of Osmanabad, Maharashtra, India; 3. Department of Chemistry, 1 nanostuctured CoPt particles. S.V. Komogortsev , Shri Chhatrapati Shivaji College, Omerga, Maharashtra, India R.S. Iskhakov1, A.A. Zimin1, E.Y. Filatov2, S.V. Korenev2, Y.V. Shubin2, N.A. Chizhik1, G.Y. Yurkin1 and E.V. Eremin11. Kirensky Institute of Physics SB RAS, Krasnoyarsk, Russian DV-12. Nanostructure of Composite Film Embedded Co-ferrite Nanoparticles Prepared by Combination of EPD and Federation; 2. Nikolaev Institute of Inorganic Chemistry SB RAS, 1 1 1 Novosibirsk, Russian Federation Electroplating. Y. Hayashi , W. Goto , S. Hashi and K. Ishiyama11. Research Institute of Electrical Communication, Tohoku University, Sendai, Miyagi, Japan DV-04. Model L10 FeNi Thin Films for Development of Rare-Earth Free Permanent Magnets. K. Barmak1, J. Liu1, N. Bordeaux2, A. Mubarok3, J.I. Goldstein3 and L.H. Lewis21. Applied Physics DV-13. Enhanced magnetic properties in Ni0.7Zn0.3Fe2O4/Sr0.8La0.2Fe11.8Co0.2O19 multilayer film. and Applied Mathematics, Columbia University, New York, NY; 2. 1 Chemical Engineering, Northeastern University, Boston, MA; 3. Z. Zi 1. Key Laboratory of Materials Physics, Institute of Solid Mechanical and Industrial Engineering, University of State of Physics, Hefei, Anhui, China Massachusetts, Amherst, MA DV-14. Tailoring exchange anisotropy in Fe-Co-Mn nanocomposites. F. Jimenez-Villacorta1, I. McDonald1, D. Heiman2 and DV-05. Effect of thickness on magnetic dipolar and exhange 1 interactions in SmCo/FeCo/SmCo thin films. C.I. Rodriguez L.H. Lewis 1. Department of Chemical Engineering, Rodriguez1, J.R. Farias Mancilla1, J. Hernandez Paz1, Northeastern University, Boston, MA; 2. Department of Physics, J.I. Betancourt Reyes3, S.F. Olive Méndez2 and J.T. Elizalde Northeastern University, Boston, MA Galindo11. Departamento de Física y Matematicas, Universidad Autónoma de Ciudad Juárez-Instituto de Ingeniería y Tecnologia, Cd. Juárez, Chihuahua, Mexico; 2. Centro de Invstigación de Materiales Avanzados, Cd. Juárez, Chihuahua, Mexico; 3. Universidad Autónoma de México-Instituto de Investigación en Materiales, Ciudad de México, D.F., Mexico

DV-06. Magnetic properties of epitaxially grown Sm2Fe17Nx thin films. Y. Hirayama1, Y. Takahashi1 and K. Hono11. Elements Strategy Center for Magnetic Materials, National Institute for Materials Science, Tsukuba, Japan 158 PROGRAM PROGRAM 159

WEDNESDAY PLAZA BALLROOM A DW-07.Size dependent magnetic properties of iron gallate nanoparticles. C. Lin1, N. Gervits2, I. Lyubutin2, Y. Tseng1, AFTERNOON 1 1 1 3,4 3 2:30 J. Lee , T. Hsu , H. Hsu , S. Ovchinnikov and I. Edelman 1. Department of Applied Physics, National Pingtung University of Education, Pingtung, Taiwan; 2. Shubnikov Institute of Session DW Crystallography, Russian Academy of Sciences, Moscow, Russian OXIDE NANOPARTICLES Federation; 3. Kirensky Institute of Physics, Siberian Branch of (Poster Session) Russian Academy of Sciences, Krasnoyarsk, Russian Federation; 4. Institute of Engineering Physics and Radioelectronics, Siberian Miguel Angel Garcia, Chair Federal University, Krasnoyarsk, Russian Federation

DW-01.Large magnetoresistance at room temperature in DW-08.Solution Processed Ferrite Nano-sheet Applicable for Inkjet La2/3Ca1/3MnO3 granular nanorods synthesized by novel Patterning. T. Takahashi1, Y. Makinose1, T. Ihara1, 1 2 2 1 cellulose templates. J. Zhang , Z. Wang , Z. Zhang , Z. Ding K. Katsumata1, S. Nakagawa2, K. Okada1 and N. Matsushita11. 2 and Q. Zhang 1. Department of Physics, Univ. of Sci. & Tech. of Materials and Structures Laboratory, Tokyo Institute of China, Hefei, China; 2. Center for Physics Experiments, Univ. of Technology, Yokohama-city, Kanagawa, Japan; 2. Department of Sci. & Tech. of China, Hefei, China Physical Electronics, Tokyo Institute of Technology, Oookayama, Meguro, Tokyo, Japan DW-02.Coexistence of considerable inter-particle interactions and

spin-glass behavior in La0.7Ca0.3MnO3 nanoparticles. DW-09.Interspacing dependence of spin-dependent variable range 1,2 2 3 4 2 1 T. Thanh , D. Manh , P. Phong , L. Hung , N. Phuc , T. Phan hopping for cold-pressed Fe3O4 nanoparticles. H. Yang1, 1 and S. Yu 1. Department of Physics, Chungbuk National N. Song1, X. Ren1 and Z. Cheng11. Institute of Physics, Beijing, University, Cheongju, Republic of Korea; 2. Institute of Materials China Science, Vietnam Academy of Science and Technology, Ha Noi, Viet Nam; 3. Nha Trang Pedagogic College, Nha Trang, Viet Nam; 4. University of Vinh, Nghe An, Viet Nam DW-10.Particle size dependence of heating power in MgFe2O4 nanoparticles for hyperthermia therapy application. M. Barati1, C. Selomulya2 and K. Suzuki11. Department of DW-03.Structural and magnetic properties of iron doped barium Materials Engineering, Monash University, Clayton, VIC, strontium titanate ceramic synthesized using slow injection Australia; 2. Department of Chemical Engineering, Monash 1 1 sol-gel technique.A. Thabit Abdo Saeed , B. Ruthramurthy , University, Clayton, VIC, Australia B. Ong1, H. Wong1, K. Tan2 and H. Yow31. Faculty of Engineering, Multimedia University, Cyberjaya, Selangor, Malaysia; 2. Department of Chemistry, University Putra DW-11. Temperature dependence of magnetic anisotropy constant in Malaysia, Serdang, Selangor, Malaysia; 3. Department of CoFe2O4 nanoparticles examined by Mössbauer spectroscopy. 1 Electrical and Electronic Engineering, Universiti Tunku Abdul S. Yoon 1. Dept. of Physics, Gunsan National University, Gunsan, Rahman, Kuala Lumpur, Malaysia Republic of Korea

DW-04.Magnetism of ultrasmall Sn1-xFexO2 nanoparticles: EPR and DW-12.Micromagnetic analysis of the maghemite platelet chains in 1 Mossbauer Spectroscopy Study. A. Punnoose1, K. Dodge1, the iron-mineral-based magnetoreceptor of birds.X. Zhang 1 J.J. Beltran2,1, N. Franco1, J. Chess1, J. Eixenberger1 and and G. Zhao 1. College of Physics and Electronic Engineering, C.A. Berrero21. Physics, Boise State University, Boise, ID; 2. Sichuan Normal University, Chengdu, Sichuan, China Sede de Investigación Universitaria, Universidad de Antioquia,, Medellín, Colombia DW-13.Uncoupled Surface Spin Induced Unique Magnetism in α- 1,2 1 MnO2 Nanowires. W. Li and J. Wang 1. Institute fro DW-05.Evolution of the magnetic order in Fe-doped SnO2 Superconducting and Electronic Materials, University of nanoparticles prepared by a polymer precursor Wollongong, Fairy Meadow, NSW, Australia; 2. School of method.F.H. Aragón1, R. Cohen2, L.C. Nagamine2, P. Hidalgo3 Computing, Engineering and Mathematics, University of Western and J. Coaquira11. Institute of Physics, University of Brasilia, Sydney, Sydney, NSW, Australia Brasilia, DF, Brazil; 2. Institute of Physics, University of São Paulo, São Paulo, SP, Brazil; 3. FaculdadeGama, Gama- University of Brasilia, Gama, DF, Brazil

DW-06.Magnetic properties of Mn-doped Fe3O4 multi-granule nanoclusters. Y. Choi1, H. Yoon1, J. Lee1, J. Wu2 and Y. Kim11. material science and engineering, Korea University, Seoul, Republic of Korea; 2. Pioneer Research Center for biomedical nanocrystal, Seoul, Republic of Korea 160 PROGRAM PROGRAM 161

WEDNESDAY PLAZA BALLROOM A DX-08. Magnetization Switching in Asymmetric Co Rings. F. Xu 1, AFTERNOON J. Wei1 and S. Li21. School of Materials Science and Engineering, 2:30 Nanjing University of Science and Technology, Nanjing, Jiangsu, China; 2. College of Physical Science, Qingdao University, Session DX Qingdao, China MICROMAGNETIC MODELING II DX-09. Magnetization Reversal of Sierpinski Fractal Structure In (Poster Session) Thin Permalloy Films.Y. Dai1, H. Wang1, T. Yang1, W. Ren1, Vitali Lomakin, Chair S. Ma1 and Z. Zhang11. Shenyang National Laboratory for Material Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang, China DX-01. Micromagnetic study of magnetization processes in patterned media deposited using polystyrene sphere array masks. L. Stoleriu1, R. Tanasa1, A. Stancu1, A. Markou2 and DX-10. Controlling the vortex core of thin Permalloy nano-cylinders I. Panagiotopoulos21. Al. I. Cuza University, Iasi, Romania; 2. dipolar coupled to Co polarizers. A.L. Dantas2 and University of Ioannina, Ioannina, Greece A.S. Carriço11. Department of Physics, Universidade Federal do Rio Grande do Norte, Natal, RN, Brazil; 2. Department of Physics, University of State of Rio Grande do Norte, Mossoro, DX-02. Effect of the Gilbert Damping Constant on the Switching RN, Brazil Current in Nanopillars with Perpendicular Anisotropy. S. Nakamura1, K. Yamada1, K. Oomaru1, T. Sato1 and Y. Nakatani11. Univercity of Electoro Communications, Chofu, DX-11. Spin-Cherenkov Effect and magnonic Mach cones. M. Yan1, Japan A. Kákay2, C. Andreas2,3 and R. Hertel31. Physics, Shanghai University, Shanghai, China; 2. 2Peter Grünberg Institut (PGI-6), Forschungszentrum Jülich, Jülich, Germany, Jülich, Germany; 3. DX-03. A Fourth Order Demagnetization Tensor for Rectangular 3Institut de Physique et Chimie des Matériaux de Strasbourg, Prisms. M.J. Donahue11. Applied and Computational Université de Strasbourg, Strasbourg, France Mathematics Division, National Institute of Standards and Technology, Gaithersburg, MD DX-12. Atomistic Spin Model based on Molecular Dynamic Method: Studies of Temperature Dependent Magnetic Properties of DX-04. Magnetic properties of multisegmented cylindrical Cobalt. M. Zhang1 and D. Wei11. School of Materials Science and nanoparticles with alternating magnetic wire and tube Engineering, Tsinghua University, Beijing, China segments.D. Salazar-Aravena1, R.M. Corona1, D. Goerlitz2, K. Nielsch2 and J. Escrig11. Departamento de Física,

Universidad de Santiago Chile, Santiago, Chile; 2. Institute of DX-13. Micromagnetic study of a single Fe3O4 nanoparticle detection Applied Physics, University of Hamburg, Hamburg, Germany using a GMR based sensor. Y. Liang1, D. Litvinov1,2 and L. Chang21. Dept. of Chemical and Biomolecular Engineering, University of Houston, Houston, TX; 2. Dept. of Electrical and DX-05. Magnetization reversal in asymmetric trilayer dots: Effect of Computer Engineering, University of Houston, Houston, TX the interlayer magnetostatic coupling. Z. Yan1 and X. Fan11. Key Lab. for Magnetism and Magnetic Materials of the Ministry of Education, Lanzhou University, Lanzhou, Gansu Province, China THURSDAY PLAZA BALLROOM BC DX-06. Magnetoresistance properties of permalloy nanostructures 1 1,2 MORNING with domain wall pinning geometry. A. Manzin , V. Nabaei , 8:30 H. Corte3, O. Kazakova3, P. Krzysteczko4 and H. Schumacher41. Istituto Nazionale di Ricerca Metrologica (INRIM), Torino, Italy; 2. Dipartimento Energia, Politecnico di Torino, Torino, Italy; 3. Session EA National Physical Laboratory (NPL), Teddington, United SYMPOSIUM ON TRENDS IN MAGNETIC Kingdom; 4. Physikalisch-Technische Bundesanstalt (PTB), IMAGING Braunschweig, Germany Dario Arena, Chair

DX-07. Magnetic-field-sensing mechanism with single elliptical magnetic layer based on dual vortex motion and magnetic 8:30 1 2 3 1 1 noise. T. Zeng , Y. Zhou , K. Lin , P. Lai and P. Pong 1. EA-01. Magnetic Scanning Gate Microscopy of Graphene and 2DEG Electrical and Electronic Engineering, The University of Hong nanodevices. (Invited) O. Kazakova1, V. Panchal1,2, Kong, Hong Kong, Hong Kong; 2. Physics, The University of R.K. Rajkumar1,3, A. Manzin4,1 and A. Asenjo5,11. NPL, Hong Kong, Hong Kong, Hong Kong; 3. Materials Science and Teddington, Middlesex, United Kingdom; 2. RHUL, Egham, Engineering, National Chung Hsing University, Tai Chung, United Kingdom; 3. Univ. of Surrey, Guilford, United Kingdom; 4. Taiwan INRIM, Turin, Italy; 5. ICMM, Madrid, Spain 162 PROGRAM PROGRAM 163

9:06 THURSDAY PLAZA BALLROOM F EA-02. Probing Magnetism at High Spatial Resolution by Aberration MORNING Corrected Electron Microscopy and Spectroscopy. (Invited) 8:30 J. Salafranca1,2, N. Biskup1,2, V. Mehta3,4, Y. Suzuki4,5, N. Perez6, A. Labarta6, X. Batlle6, S.T. Pantelides7, S.J. Pennycook2 and Session EB 2,1 M. Varela 1. Dpt Fisica Aplicada III & Instituto Pluridisciplinar, TUNNELING AND SPIN TRANSPORT I Universidad Complutense de Madrid, Madrid, Spain; 2. Materials Science and Technology Division, Oak Ridge National Xiufeng Han, Chair Laboratory, Oak Ridge, TN; 3. University of California, Berkeley, CA; 4. Lawrence Berkeley National Laboratory, Berkeley, CA; 5. 8:30 Stanford University, Stanford, CA; 6. Universitat de Barcelona, 1,2 Barcelona, Spain; 7. Vanderbilt University, Nashville, TN EB-01. Spintronics with Antiferromagnets. (Invited) X. Marti , I. Fina4,5, J. Clarkson3, R. Paul3, J. Heron3, C. Nelson7, J. Liu3,7, J. Chu3,7, J. Zelezny2, C. Rayan-Serrao3, J. Kudrnovsky2, 9:42 I. Turek1,2, J. Fontcuberta4, T. Jungwirth2,6 and R. Ramesh3,71. EA-03. Direct Imaging of Non-Adiabatic Spin Torque Effects on Charles University in Prague, Prague, Czech Republic; 2. Vortex Core Orbits with Electrons. (Invited) S.D. Pollard1,2, Academy of Sciences of the Czech Republic, Prague, Czech L. Huang1,2, K.S. Buchanan3, D.A. Arena1 and Y. Zhu1,21. Republic; 3. University of California Berkeley, Berkeley, CA; 4. Brookhaven National Laboratory, Upton, NY; 2. Stony Brook Institut de Ciencia de Materials de Barcelona, Barcelona, Spain; University, Stony Brook, NY; 3. Colorado State University, Fort 5. Max Planck Institute - Halle, Halle, Germany; 6. University of Collins, CO Nottingham, Nottingham, United Kingdom; 7. Lawrence Berkeley National Laboratory, Berkeley, CA

10:18 9:06 EA-04. Analysis of Hidden and Internal Magnetic Domains. (Invited) R. Schaefer11. Leibniz Institute for Solid State and Materials EB-02. Proximity-induced magnetoresistance in topological insulator 1 2 1 Research (IFW) Dresden, Dresden, Germany thin films on YIG. M. Lang , M.C. Onbasli , K. Yao , M. Montazeri1, L. He1, C.A. Ross2 and K.L. Wang11. Department of Electrical Engineering, University of California, Los Angeles, 10:54 Los Angeles, CA; 2. Department of Materials Science and EA-05. X-ray holographic microscopy of magnetic nanostructures. Engineering, Massachusetts Institute of Technology, Cambridge, (Invited) R. Frömter1, J. Bach1, B. Beyersdorff1, C. Weier3, MA S. Schleizer2, L. Müller2, C. Gutt2, G. Grübel2 and H. Oepen11. Institut für Angewandte Physik, Universität Hamburg, Hamburg, 9:18 Germany; 2. Deutsches Elektronen-Synchrotron (DESY), Hamburg, Germany; 3. PGI, Forschungszentrum Jülich, Jülich, EB-03. General characteristics of angular dependence of anisotropic 1 1 Germany magnetoresistance. S. Zhang and S. Zhang 1. university of arizona, Tucson, AZ

9:30 EB-04. Magneto-Seebeck effect on different substrate materials: Time resolved measurements and simulations on a single magnetic tunnel junction. A. Boehnke1, M. Walter2, N. Roschewsky2, T. Eggebrecht2, V. Drewello1, K. Rott1, M. Münzenberg2, A. Thomas1 and G. Reiss11. Thin Films and Physics of Nanostructures, Bielefeld University, Bielefeld, Germany; 2. I. Physikalisches Institut, Georg-August-Universität Göttingen, Göttingen, Germany

9:42 EB-05. Tuning Thermally Driven Currents and Spins in Nanometer Scale Devices by Electronic Design. (Invited) C. Heiliger11. I. Physikalisches Institut, Justus Liebig University, Giessen, Germany 164 PROGRAM PROGRAM 165

10:18 THURSDAY PLAZA BALLROOM E EB-06. Nanospintronics investigated using scanning tunnelling MORNING microscopy (STM) in individual nanometre-scale double 8:30 magnetic tunnel junctions. R. Temple1 and C.H. Marrows11. University of Leeds, Leeds, United Kingdom Session EC SPIN-CALORITRONICS AND SPIN HALL 10:30 EFFECTS EB-07. Traps and trions at the origin of magnetic field effects in Matthew Pufall, Chair organic semiconductors.M. Cox1, P. Janssen1, I. van der Heijden1, F. Zhu1 and B. Koopmans11. Physics, Eindhoven 8:30 University of Technology, Eindhoven, Netherlands EC-01. Giant thermal spin accumulation in NLSV structure by using 1,2 10:42 CoFeAl/Cu interface at room temperature. S. Hu and T. Kimura1,31. Inamori Frontier Research Center, Kyushu EB-08. Localization and anomalous Hall effect in the amorphous university, Fukuoka, Japan; 2. Graduate School of Information CoFeB thin films. T. Zhu1, S. Wu1,2, X. Yang2 and S. Chen21. Science and Electrical Engineering, Kyushu University, Fukuoka, Institute of Physics, Chinese Academy of Sciences, Beijing, China; Japan; 3. Department of Physics, Kyushu University, Fukuoka, 2. Department of Electronic Science and Technology, Huazhong Japan University of Science and Technology, Wuhan, China 8:42 10:54 EC-02. Determination of the origin of the spin Seebeck effect - bulk EB-09. First-principles study on the relationship between magnetic vs. interface effects. M. Klaeui1, A. Kehlberger1, R. Roeser1, 1 2 2 2 3 anisotropy and anomalous Hall effect of bct-Fe50Co50 alloy. G. Jakob , U. Ritzmann , D. Hinzke , U. Nowak , M.C. Onbasli , K. Hyodo1, Y. Kota2 and A. Sakuma11. Department of Applied D. Kim3, C.A. Ross3, M.B. Jungfleisch4 and B. Hillebrands41. Physics, Tohoku University, Sendai, Japan; 2. Spintronics Institute of Physics, Johannes Gutenberg Universität Mainz, Research Center, National Institute of advanced Industrial Mainz, Germany; 2. Department of Physics, University of Science and Technology, Tsukuba, Japan Konstanz, Konstanz, Germany; 3. Department of Materials Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA; 4. Fachbereich Physik and 11:06 Landesforschungszentrum OPTIMAS, Technische Universität EB-10. Anisotropic Magnetroresistance in Co/Pt nano-contacts Kaiserslautern, Kaiserslautern, Germany through Alumina barrier. M. Al-Mahdawi1 and M. Sahashi11. Electronic engineering, Tohoku Univ, Sendai, Miyagi, Japan 8:54 EC-03. Anomalous Nernst and spin Seebeck contributions in Pt/NiFe 11:18 bilayer structures. Y. Xu 1, T. Lin1 and J. Shi11. Department of EB-11. Detrimental role of interface states in CoFe2O4 spin-filter Physics and Astronomy, Univ. of California, Riverside, Riverside, tunnel junctions. P.V. Lukashev1, J.D. Burton1, A. Smogunov2, CA J.P. Velev3 and E.Y. Tsymbal11. Physics and Astronomy, University of Nebraska - Lincoln, Lincoln, NE; 2. CEA, Institut 9:06 Rayonnement Matière de Saclay, SPCSI, Gif-sur-Yvette, France; 3. Physics, Institute for Functional Nanomaterials, University of EC-04. Peltier, Seebeck, and Nernst Effects in Ferromagnetic Metals Puerto Rico, San Juan, Puerto Rico with In-Plane Thermal Gradients. (Invited) B. Zink11. University of Denver, Denver, CO

9:42 EC-05. DC Measurements of Spin and Heat Transport in Lateral Spin Valves. J.T. Batley1, J.D. Witt1, M.C. Rosamond2, G. Burnell1 and B.J. Hickey11. Physics and Astronomy, University of Leeds, Leeds, United Kingdom; 2. Electronic and Electrical Engineering, University of Leeds, Leeds, United Kingdom 166 PROGRAM PROGRAM 167

9:54 THURSDAY PLAZA BALLROOM D EC-06. Evaluation of Transition Metal Films for Spin-Thermoelectric MORNING Conversion. M. Ishida1, A. Kirihara1, K. Uchida2,3, S. Kohmoto1, 8:30 E. Saitoh4,5 and T. Murakami11. NEC Corp., Tsukuba, Japan; 2. Institute for Materials Research, Tohoku University, Sendai, Session ED Japan; 3. PRESTO, Japan Science and Technology Agency, ELECTRONIC STRUCTURE AND CRITICAL Saitama, Japan; 4. IMR/WPI-AIMR, Tohoku University, Sendai, Japan; 5. ASRC-JAEA/CREST-JST, Tokai/Tokyo, Japan PHENOMENA Kirill Belashchenko, Chair 10:06 8:30 EC-07. Self-consistent determination of spin Hall angles of selected 5d 1 1 1,2 metals by thermal spin injection. D. Qu , S. Huang , B. Miao ED-01. Magnetic collapse and crystalline-to-amorphous transition and C. Chien11. Department of Physics and Astronomy, Johns induced by high pressure in type-I clathrate Eu8Ga16Ge30 Hopkins University, Baltimore, MD; 2. National Laboratory of J. Linares Mardegan1,2, G. Fabbris2,3, L. Veiga1,4, C. Adriano1, Solid State Microstructures and Department of Physics, Nanjing F. Lussani1, M.A. Avila5, D. Haskel2 and C. Giles11. Instituo de University, Nanjing, China Fisica Gleb Wataghin, State University of Campinas, Campinas, São Paulo, Brazil; 2. Advanced Photon Source, Argonne National 10:18 Laboratory, Argonne, IL; 3. Department of Physics, Washington University, St. Louis, MO; 4. Laboratorio Nacional de Luz EC-08. Magnon-Drag Thermopower in FePt Thin Films. H. Xing1, Sincrotron, Campinas, São Paulo, Brazil; 5. CCNH, Universidade G. Hu2, R. Sabirianov3 and H. Zeng11. Physics, SUNY-Buffalo, Federal do ABC (UFABC), Santo Andre, São Paulo, Brazil Buffalo, NY; 2. IBM T.J. Watson Research Center, Yorktown Heights, NY; 3. Physics, University of Nebraska-Omaha, Omaha, 8:42 NE ED-02. Angular Dependence of the X-ray Magnetic Linear Dichroism 10:30 in Reflection at the 3p Edges of the ferromagnetic Fe, Ni, and Co - Theory and Experiment. D. Legut1, J. Hamrle1, EC-09. Spin Seebeck and Spin Hall magnetoresistance in Pt/YIG P. Oppeneer2, M. Tesch3, H. Mertins3, M. Gilbert3, A. Gaupp4 and films grown by RF sputtering. S. Marmion1, L. Roach1, D. Buergler51. Nanotechnology Centre, VSB Tech. Univ. Ostrava, M. McLaren1, M. Ali1, D. Williams2 and B. Hickey11. Physics, Ostrava, Czech Republic; 2. Department of Physics and University of leeds, Leeds, United Kingdom; 2. Hitachi Astronomy, Uppsala University, Uppsala, Sweden; 3. FH laboratory, Cambridge, United Kingdom Muenster, Steinfurt, Germany; 4. HZB Berlin, Berlin, Germany; 5. FZ Juelich, Juelich, Germany 10:42 8:54 EC-10. Inverse Spin Hall Effect in a Ferromagnetic Metal. B. Miao1,2, S. Huang1, D. Qu1 and C. Chien11. Department of Physics and ED-03. ARPES investigation of giant Rashba in GeTe. C. Rinaldi1, Astronomy, Johns Hopkins University, Baltimore, MD; 2. National I. Vobornik2, M. Cantoni1, A. Giussani3, R. Calarco3, D. Di Sante4, Laboratory of Solid State Microstructures and Department of S. Picozzi4, G. Panaccione2, J. Krempasky5 and R. Bertacco11. Physics, Nanjing University, Nanjing, Jiangsu, China Physics, Politecnico di Milano, Como, Italy; 2. TASC Laboratory, Elettra Synchrotron IOM-CNR, Trieste, Trieste, Italy; 3. Department of Epitaxy, Paul Drude Institute for 10:54 Festkörperelektronik, Berlin, Germany; 4. CNR-SPIN, L’Aquila, EC-11. Manipulating spin pumping and Inverse Spin Hall Effect with Italy; 5. Paul Scherrer Institute (PIS), Villligen, Switzerland crystal structure in Fe/Pt bilayers. E. Papaioannou1, P. Fuhrmann1, T. Brächer1, B. Jungfleisch1 and B. Hillebrands11. 9:06 Physics, TU Kaiserslautern, Kaiserslautern, Germany ED-04. Temperature dependent electronic structure of Pr Sr MnO film probed by X-ray Absorption Near Edge 11:06 0.67 0.33 3 Structure.B. Zhang1,2, C. Sun1, J. Chen2,3, V.T. Venky3,4, EC-12. Spin Pumping from View Point of Linear Response Approach. S.M. Heald1 and G. Chow21. Advanced Photon Source, Argonne K. Chen1 and S. Zhang11. University of Arizona, Tucson, AZ National Laboratory, Argonne, IL; 2. Materials Science and Engineering, National University of Singapore, Singapore, Singapore; 3. NUSNNI-Nanocore, National University of 11:18 Singapore, Singapore, Singapore; 4. Physics, National University EC-13. Electric detection of parametric spin wave resonance in of Singapore, Singapore, Singapore permalloy/platinum nanowires. L. Yang1, Z. Duan1, A. Smith1, B. Youngblood1 and I. Krivorotov11. Physics and Astronomy, University of California, Irvine, Irvine, CA 168 PROGRAM PROGRAM 169

9:18 11:06 ED-05. First-Principles Investigation on the Magnetic Properties of ED-12. Tailored exchange in binary manganese–noble metal alloys. Tetragonal and Hexagonal MnFeAs. Y. Zhang1 and F. Jimenez-Villacorta1, D. Heiman2 and L.H. Lewis11. G.J. Miller11. Chemistry, Iowa State University, Ames, IA Department of Chemical Engineering, Northeastern University, Boston, MA; 2. Department of Physics, Northeastern University, Boston, MA 9:30

ED-06. The cause of pressure dependence on electronic structure of 11:18 Gd.N. Kamali Sarvestani1, S. Ketabi1 and A. Yazdani21. Physics, Damghan University, Damghan, Islamic Republic of Iran; 2. ED-13. Prediction and Confirmation of Elemental Substitution Physics, Tarbiat Modares Univiesity, Tehran, Islamic Republic of Effects in FeRh-based compounds. R. Barua1, F. Jiménez- Iran Villacorta1 and L.H. Lewis11. Chemical Engineering, Northeastern University, Boston, MA 9:42 ED-07. First Principles Based Calculation of Finite Temperature Magnetism in Ni. M. Eisenbach1, J. Yin1, J. Li1 and D.M. Nicholson11. Oak Ridge National Laboratory, Oak Ridge, THURSDAY GOVERNOR’S SQ 14 TN MORNING 8:30 9:54

1 Session EE ED-08. Orbital, charge, and spin couplings in Ba3BiRu2O9T. Liu , T. Jia1, X.L. Zhang1, Z. Zeng1 and H.Q. Lin21. Key Laboratory of MAGNETIC NANOPARTICLES II Materials Physics, Institute of Solid State Physics, Chinese Adrian Quesada, Chair Academy of Sciences, and Department of Physics, University of Science and Technology of China, Hefei, China; 2. Beijing Computational Science Research Center, Beijing, China 8:30

EE-01. Energetics of Canted Fe3O4 Nanoparticles Studied with 1 10:06 Polarized Neutron Scattering. (Invited) K.L. Krycka 1. NCNR, NIST, Gaithersburg, MD ED-09. Magnetic transition behavior in epitaxial Fe47Rh47Pd6 films. P.R. LeClair1, H. Sato1, S. Keshavarz1, N. Pachauri1, H. Lee1, G.J. Mankey1 and O. Myrasov11. University of Alabama, 9:06 Tuscaloosa, AL EE-02. Controlled Nucleation of Magnetic Islands. F.Q. Zhu1, S. Wang1, R. Ruiz1, M. Schabes1, H. Zou1, B. Terris1 and 1 10:18 B. Gurney 1. HGST, San Jose, CA ED-10. Driving magneto-structural phase transitions in layered 1 1,2 9:18 RMn2X2 Compounds. (Invited) S.J. Kennedy , J. Wang , 3 4 2 S.J. Campbell , M. Hofmann and S. Dou 1. Bragg Institute, EE-03. Modification of Structural and Dynamic Properties of Iron Australian Nuclear Science and Technology Organisation, Lucas Oxide Nanocrystals by Terbium-Doping. K. Rice1, S. Russek1, Heights, NSW, Australia; 2. Institute for Superconductivity and R. Geiss1, Y. Idzerda2, J. Shaw1, E. Evarts1, R. Usselman1 and Electronic Materials, University of Wollongong, Wollongong, T. Silva11. NIST, Boulder, CO; 2. Montana State University, NSW, Australia; 3. School of Physical, Environmental and Bozeman, MT Mathematical Sciences, University of New South Wales, Canberra, ACT, Australia; 4. Forschungs-Neutronenquelle Heinz Maier-Leibnitz, Technische Universität München, Garching, 9:30 Germany EE-04. Synthesis and Characterization of Bimagnetic FePt-Fe3O4 Octapod with Hetero-structure.W. Li 1, M. Zhou1, M. Zhu1, 10:54 D. Zhou1 and Y. Hou21. Central Iron and Steel Research Institute, Beijing, China; 2. Peking University, beijing, China ED-11. The Verwey transition in nanostructured magnetite produced by a combination of chimie douce and spark plasma sintering.T. Gaudisson2, G. Vazquez-Victorio1, M. Banobre- Lopez3, S. Nowak2, J. Rivas3, S. Ammar2 and R. Valenzuela11. Materials Science, National Autonomous University of Mexico, Mexico, DF, Mexico; 2. ITODYS, Universite Paris Diderot, CNRS-UMR 7086, Paris, Paris, France; 3. International Iberian Nanotechnology Laboratory, Braga, Portugal 170 PROGRAM PROGRAM 171

9:42 THURSDAY GOVERNOR’S SQ 15 EE-05. Spin freezing and inverse magnetocaloric effect in core/shell MORNING and hollow nanostructures. S. Chandra1, A. Biswas1, 8:30 H. Khurshid1, W. Li2, G.C. Hadjipanayis2 and H. Srikanth11. Department of Physics, University of South Florida, Tampa, FL; Session EF 2. Department of Physics and Astronomy, University of Delaware, Fe- AND Re-BASED MAGNETOCALORICS Newark, DE Ekkes Brück, Chair

9:54 8:30 EE-06. Epitaxial antiferromagnetic-ferrimagnetic core-shell nanocrystals. S. Liao1, Y. Chen2, W. Kuo3, J. Cheung4, H. Kuo2, EF-01. Impacts of first-order magnetic transition and phase W. Lin5, X. Cheng4, Y. Chen1, Y. Chen5, H. Liu2, H. Lin5, coexistence on the universal behavior of inverse 1 1 1 J. Juang3, Y. Chueh1, N. Valanoor4, Y. Chu2 and C. Lai11. magnetocaloric effect. A. Biswas , P. Lampen , N.S. Bingham , 2 2 1 1 Materials Science & Engineering, National Tsing Hua University, T.L. Phan , S.C. Yu , M.H. Phan and H. Srikanth 1. Department Hsinchu, Taiwan; 2. Department of Materials Science & of Physics, University of South Florida, Tampa, FL; 2. Engineering, National Chiao Tung University, Hsinchu, Taiwan; Department of Physics, Chungbuk National University, Cheongju, 3. Department of Electrophysics, National Chiao Tung University, Republic of Korea Hsinchu, Taiwan; 4. School of Materials Science and Engineering, University of New South Wales, Sydney, NSW, 8:42 Australia; 5. National Synchrotron Radiation Research Center, Hsinchu, Taiwan EF-02. Effects of Cr doping on structural and magnetic properties of 1,4 1,2 La0.7Pr0.3Fe11.4Si1.6 compound. M. Md Din , J. Wang , S. Kennedy2, A. Studer2, S. Campbell3 and S. Dou11. Institute of 10:06 Superconducting and Electronic Material, University of EE-07. Effect of Synthetic Method on the Magnetic Properties of Iron Wollongong, Wollongong, NSW, Australia; 2. Bragg Institute, Oxide Nanoparticles.S. Majetich1, T. Wen1, R.A. Booth1, Australian Nuclear Science and Technology Organization, Lucas S.D. Oberdick1, L. Lari2 and V. Lazarov21. Physics, Carnegie Heights, NSW, Australia; 3. School of Physical, Environmental Mellon University, Pittsburgh, PA; 2. Physics, University of York, and Mathematical Sciences, The University of New South Wales, York, United Kingdom Canberra, ACT 2600, ACT, Australia; 4. Department of Electrical & Electronic Engineering, Faculty of Engineering, National Defence University of Malaysia, Kem Sungai Besi 57000, Kuala 10:18 Lumpur, Malaysia

EE-08. Optical properties of L10 FePt nanoparticles dispersed in a C 1 1 1 1 1 1 matrix. Z. Cen , B. Xu , J. Hu , S. Ng , J. Shanmugam , Y. Toh , 8:54 J. Li1, K. Ye1 and J. Zhang11. Data storage institute, Agency for Science, Technology and Research (A-STAR), Singapore, EF-03. Porous heat exchangers made of polymer-bonded 1 1 1,2 Singapore La(Fe,Si)13Hx. K.P. Skokov , M.D. Kuzmin , D.Y. Karpenkov , I.A. Radulov1, B. Kaesewurm1, M. Fries1, T. Gotschall1 and O. Gutfleisch1,31. Functional materials, Tecnical University, 10:30 Darmstadt, Hessen, Germany; 2. Physics faculty, State University, EE-09. Non-Linear Magnetic SHG and Magneto-Transport in Au-Co Tver, Russian Federation; 3. ISC IWKS, Fraunhofer, Hanau, Nanocomposite Films. K. Yang1, V. Kryutyanskiy2, Germany I. Kolmychek2, T.V. Murzina2 and R.A. Lukaszew31. Department of Applied Science, College of William and Mary, Williamsburg, 9:06 VA; 2. Department of Physics, Moscow State University, Moscow, Moscow, Russian Federation; 3. Department of Physics, College EF-04. Enhancement of refrigerant capacity in Fe-based soft 1 1 of William and Mary, Williamsburg, VA magnetic amorphous bilayer ribbons.J. Marcin , J. Kovac , J. Hosko2, P. Svec2 and I. Skorvanek11. Magnetism, Institute of Experimental Physics Slov. Acad. Sci., Kosice, Slovakia; 2. 10:42 Institute of Physics Slo. Acad. Sci., Bratislava, Slovakia EE-10. Magneto-optical properties of biogenic photonic crystals in 1,2 1 algae. M. Iwasaka and Y. Mizukawa 1. Chiba University, 9:18 Chiba, Japan; 2. JST PRESTO, Kawaguchi, Japan EF-05. Effect of annealing on the structure and magnetic entropy change of Mn1.1Fe0.9P0.8Ge0.2 ribbons. J. Liu1, Y. Shao1, 10:54 Y. Zhang1, M. Zhang1 and A. Yan11. Ningbo Institute of Materials Technology and Engineering, CAS, Ningbo, China EE-11. Low TC Fe-Cr-Nb-B glassy nanopowders for hyperthermia applications. H. Chiriac1, N. Lupu1, M. Lostun1, G. Ababei1, M. Grigoras1 and C. Danceanu11. National Institute of R&D for Technical Physics, Iasi, Romania 172 PROGRAM PROGRAM 173

9:30 10:54 EF-06. Magnetic entropy changes and enhanced refrigeration EF-13. Use of Analysis of Variance to Create a Methodology for capacity in chemically-modified FeRh compounds. R. Barua1, Analyzing Universal Scaling in Magneto-Caloric Materials. F. Jiménez-Villacorta1 and L.H. Lewis11. Chemical Engineering, D.D. Belyea1 and C.W. Miller11. Physics, University of South Northeastern University, Boston, MA Florida, Tampa, FL

9:42 11:06 EF-07. Origin of the tunable phase transition process by Si EF-14. Deconvolution of the magnetocaloric response of multiphase substitution in Mn1.25Fe0.70P1-xSix compounds. X. Miao1, materials. V. Franco1, J.S. Blázquez1, A. Conde1, J. Marcin2 and L. Caron1, P. Roy2, N.H. Dung1, L. Zhang1,3, Z.Q. Ou1, I. Škorvánek21. Department of Condensed Matter Physics, Sevilla W.A. Kockelmann4, R. Smith4, R.A. de Groot2, N.H. van Dijk1 University, Sevilla, Spain; 2. Institute of Experimental Physics, and E. Bruck11. Delft University of Technology, Delft, Slovak Academy of Sciences, Košice, Slovakia Netherlands; 2. Radboud University, Nijmegen, Netherlands; 3. BASF Nederland B.V., De Meern, Netherlands; 4. ISIS, 11:18 Rutherford Appleton Laboratory, Chilton, United Kingdom EF-15. Broadening the magnetic entropy change and its correlation 9:54 with the Curie temperature distribution in high-energy ball milled R2Fe17 alloys.P. Álvarez-Alonso1, J. Sánchez- EF-08. Thermomagnetic Energy Conversion Efficiency near the Llamazares2, G.J. Cuello3, V. Franco4, P. Gorria5 and Transition Point for Nickel Nanostructures. S.M. Sandoval1 and J.A. Blanco51. Departamento de Electricidad y Electrónica, G.P. Carman11. MAE, UCLA, Los Angeles, CA Universidad del País Vasco, Leioa, Spain; 2. División de Materiales Avanzados, Instituto Potosino de Investigación Científica y Tecnológica, San Luis Potosí, Mexico; 3. Institute 10:06 Laue Langevin, Grenoble, France; 4. Departamento de Física de EF-09. The large cryogenic magnetocaloric effect of anti- la Materia Condensada, Universidad de Sevilla, Sevilla, Spain; 5. ferromangetic GdH2 nanoparticles.J. Li1, S. Ma1, H. Wang1, Departamento de Física, Universidad de Oviedo, Gijón, Spain W. Gong1, J. Jiang1, S. Li1, Y. Wang1, D. Geng1 and Z. Zhang11. Institute of Metal Research,CAS, Shenyang city, Liaoning, China

10:18 THURSDAY GOVERNOR’S SQ 16 2 1 EF-10. On the magnetic ordering of Gd5Ge3J.M. Cadogan , D. Ryan , MORNING 3 3 3 Y. Mudryk , V.K. Pecharsky and K.A. Gschneidner 1. Physics, 8:30 McGill University, Montreal, QC, Canada; 2. School of Physical, Environmental and Mathematical Sciences, UNSW Canberra at the Australian Defence Force Academy, Canberra, ACT, Session EG Australia; 3. Department of Materials Science and Engineering, TRANSFORMERS AND INDUCTORS Iowa State University, Ames, IA Hongbin Yu, Chair

10:30 8:30 EF-11. Evolution of magnetic properties and magnetocaloric effect in EG-01. The Need for Thick Conformal Magnetic Coatings for 1,3 TmNi1-xCuxAl (x=0, 0.3, 0.5, 0.7, 0.9, 1) compounds. Z. Mo , Integrated Inductors with High Quality Factors. J.A. Bain11. 3 1 2 3 1 1 2 J. Shen , G. Chen , L. Yan , J. Wu , C. Tang , J. Lin , J. Sun and ECE, Carnegie Mellon University, Pittsburgh, PA B. Shen21. School of Material Science and Engineering,, Hebei University of Technology, Tianjin, China; 2. State Key Laboratory of Magnetism, Beijing National Laboratory for Condensed 8:42 Matter, Physics and Institute of Physics,, Chinese Academy of EG-02. High Q Integrated GHz Magnetic Transformers with Sciences, Beijing, China; 3. Key laboratory of cryogenics, FeGaB/Al2O3 Multilayer Films for RFIC Applications. Technical Institute of Physics and Chemistry, Chinese Academy of Y. Gao1, S. Zare1, X. Yang1, T. Nan1, Z. Zhou1, M. Onabajo1 and Sciences, Beijing, China N. Sun11. Electrical and Computer Engineering, Northeastern University, Boston, MA 10:42 EF-12. Magnetic and magnetocaloric properties of some rare earth 8:54 1 2 based metal organic frameworks. N.K. Singh , S. Gupta , EG-03. Magnetic Field Emissions for Ferrite and Non- Ferrite 2 1 V.K. Pecharsky and V.P. Balema 1. Aldrich Materials Science, Geometries for Wireless Power Transfer to Vehicles. T. Batra1 Sigma Aldrich Corp., Milwaukee, WI; 2. The Ames Laboratory, and E. Schaltz11. Department of Energy Technology, Aalborg Iowa State University, Ames, IA University, Aalborg, Denmark 174 PROGRAM PROGRAM 175

9:06 10:30 EG-04. Effects of High Frequency and Hybrid-Typed Structure of EG-11. Effects of Magnetostriction and Magnetic Reluctances on Magnetic Properties on Thin Film Core with Amorphous Magnetic Properties of Distribution Transformers. C. Lee1, Materials. C. Hsu1,3, C. Lee2, S. Cheng3, C. Lin2, C. Liao2, C. Hsu2, C. Tseng3, C. Feng1, H. Yu1 and C. Chen11. Department C. Feng2, H. Yu2 and C. Chen21. Division of Electrical of Electrical Engineering, Chung Yuan Christian University, Tao- Engineering, Fortune Electric Co., Ltd., Tao-Yuan, Taiwan; 2. Yuan, Taiwan; 2. Division of Electrical Engineering, Fortune Department of Electrical Engineering, Chung Yuan Christian Electric Co., Ltd, Tao-Yuan, Taiwan; 3. Division of Physics, University, Tao-Yuan, Taiwan; 3. Department of Power Institute of Nuclear Energy Research, Tao-Yuan, Taiwan Mechanical Engineering, Army Academy R.O.C., Tao-Yuan, Taiwan 10:42

9:18 EG-12. Prediction and Control of Transformer Inrush Currents. E. Cardelli1,2, A. Faba1,2 and V. Morettini11. University of EG-05. An amorphous alloy core medium frequency magnetic-link Perugia, Perugia, Italy; 2. Industrial Engineering Center for for medium voltage photovoltaic inverters.M. Islam1, A. Guo1, Electric and Magnetic Research, University of Perugia, Perugia, G. Lei1 and P. Zhu11. Centre for Electrical Machines and Power Italy Electronics, University of Technology Sydney, Ultimo, NSW, Australia 10:54

9:30 EG-13. Development of precision broadband ac measurement system for magnetism coupling properties. J. Lu1, X. Shao1, T. Zhao1 EG-06. Proposal of Potted Inductor with Enhanced Thermal Transfer and B. Shen11. State Key Laboratory of Magnetism, Institute of for High Power Boost Converter in HEVs. B. You1, B. Lee1, Physics, Chinese Academy of Sciences, Beijing, China I. Jeong2, G. Choi2 and S. Lee21. Energy mechatronics, Sungkyunkwan Univ., Suwon, Republic of Korea; 2. R&D Center, 11:06 Changsung Corp., Incheon, Republic of Korea EG-14. High-Frequency Characteristics of Magnetostriction on Vibration and Noise for Single-Phase Transformer 9:42 Dependence of Magnetic Circuit Method. S. Cheng1, C. Feng2, EG-07. Control of magnetic flux and eddy currents in magnetic films C. Hsu1,3, H. Yu2, C. Chen2, C. Lin2 and C. Liao21. Department of for on-chip radio frequency (RF) inductors: Role of the Power Mechanical Engineering, Army Academy R.O.C., Tao- magnetic vias. H. Wu1, S. Zhao1, D.S. Gardner2 and H. Yu11. Ira Yuan, Taiwan; 2. Department of Electrical Engineering, Chung A. Fulton Schools of Engineering, Arizona State University, Yuan Christian University, Tao-Yuan, Taiwan; 3. Division of Tempe, AZ; 2. Intel Labs, Intel Corp., Santa Clara, CA Electrical Engineering, Fortune Electric Company, Ltd., Tao- Yuan, Taiwan 9:54 EG-08. Zero-footprint Ethernet transformers using circuit-board embedded ferrites. D. Bowen1, A. Lee1, C. Krafft2 and I.D. Mayergoyz1,31. Electrical and Computer Engineering THURSDAY GOVERNOR’S SQ 12 Department, University of Maryland, College Park, MD; 2. MORNING Laboratory for Physical Sciences, College Park, MD; 3. UMIACS 8:30 and AppEL, University of Maryland, College Park, MD Session EH 10:06 SPIN TRANSFER DYNAMICS EG-09. Performance effects of device scale and core aspect-ratio on Ilya Krivorotov, Chair dielectric-core circuit board transformers. D. Bowen1, A. Lee1, C. Krafft2 and I.D. Mayergoyz1,31. Electrical and Computer Engineering, University of Maryland, College Park, MD; 2. 8:30 Laboratory for Physical Sciences, College Park, MD; 3. UMIACS EH-01. High Frequency Oscillations at Small Applied Fields in a Dual and AppEL, University of Maryland, College Park, MD Free Layer Spin Torque Oscillator. P.M. Braganca1, K. Pi1, J.R. Childress1 and B.A. Gurney11. HGST, a Western Digital 10:18 Company, San Jose, CA EG-10. An embedded flexible inductor with using Fe-Si-Al powder composite films for semi-flexible boarded power converters. S. Lim1, H. Kim1, G. Han1, I. Jeong2 and G. Choi21. Electronic Systems Engineering, Hanyang Univ., Ansan, Republic of Korea; 2. R&D center, Chang Sung Corp., Incheon, Republic of Korea 176 PROGRAM PROGRAM 177

8:42 9:42 EH-02. Low-Linewidth Microwave Emission by Spin Transfer Torque EH-07. Current induced switching dynamics in perpendicular in a Single Layer Half-Heusler Film. P. Dürrenfeld1, CoFeB/MgO/CoFeB magnetic tunnel junctions for thermal S. Mohseni2, F. Gerhard3, F. Qejvanaj2,4, M. Ranjbar1, S. Redjai spin transfer torque. J.C. Leutenantsmeyer1, M. Walter1, Sani4, S. Chung4, C. Gould3, L. Molenkamp3 and J. Åkerman1,41. S. Wittrock1, V. Zbarsky1, P. Peretzki2, H. Schuhmann2, M. Seibt2 Department of Physics, University of Gothenburg, Gothenburg, and M. Münzenberg11. I. Physikalisches Institut, Goettingen Sweden; 2. Nanosc AB, Kista, Sweden; 3. Physikalisches Institut University, Goettingen, Germany; 2. IV. Physikalisches Institut, (EP3), Universität Würzburg, Würzburg, Germany; 4. Materials Goettingen University, Goettingen, Germany Physics, School of ICT, KTH Royal Institute of Technology, Kista, Sweden 9:54

8:54 EH-08. Phase synchronization in a bi-modal auto-oscillation regime. O. Klein1, G. de Loubens1, V. Naletov1 and V. Cros21. Service de EH-03. Microwave emissions in CoFeB-MgO tunnel junctions with Physique de l’État Condensé, Gif-Sur-Yvette, France; 2. Unité perpendicular-anisotropy free layer at ultralow current Mixte de Physique CNRS/Thales, Palaiseau, France densities. Z. Zeng1,2, B. Fang1, H. Jiang2, P. Khalili Amiri3 and k. Wang31. Key Laboratory of Nanodevices and Applications, 10:06 Suzhou Institute of Nano-tech and Nano-bionics, Chinese Academy of Sciences, Suzhou, Jiangsu, China; 2. Department of EH-09. Perfect synchronization of a spin transfer nano-oscillator Physics and Astronomy, University of California, Los Angeles, based on coupled magnetic vortices. A. Hamadeh1, V. Naletov1, Los Angeles, CA; 3. Department of Electrical Engineering, G. de Loubens1, N. Locatelli2, V. Cros2 and O. Klein11. Service de University of California, Los Angeles, Los Angeles, CA Physique de l’État Condensé, Gif-Sur-Yvette, France; 2. Unité Mixte de Physique CNRS/Thales, Palaiseau, France 9:06 10:18 EH-04. Novel Bias-Field-Free Large Gain Spin-Transfer Oscillator. T. Windbacher1, A. Makarov1, H. Mahmoudi1, V. Sverdlov1 and EH-10. Time-resolved Kerr imaging of magnetization dynamics S. Selberherr11. TU Wien, Institute for Microelectronics, Vienna, generated by a nano-contact spin transfer vortex oscillator. Vienna, Austria P.S. Keatley1, S.R. Sani2,3, T.J. Loughran1, J. Åkerman2,4 and R.J. Hicken11. School of Physics and Astronomy, University of 9:18 Exeter, Exeter, United Kingdom; 2. Materials Physics, KTH Royal Institute of Technology, Kista, Sweden; 3. NanOsc AB, Kista, EH-05. Self-modulation in nanocontact spin torque oscillators. Sweden; 4. Physics Department, University of Gothenburg, R.K. Dumas1, E. Iacocca1, S. Sani2,3, M. Mohseni2,3, Gothenburg, Sweden O. Heinonen4,5 and J. Åkerman1,21. Physics, University of Gothenburg, Gothenburg, Sweden; 2. Materials Physics, Royal 10:30 Institute of Techology (KTH), Kista, Sweden; 3. NanOsc AB, Kista, Sweden; 4. Materials Science Division, Argonne National EH-11. Mode-hopping, coexistence, and linewidth broadening in a Laboratory, Lemont, IL; 5. Physics, Northwestern University, two-mode spin-torque oscillator. O. Heinonen1,2, E. Iacocca3 and Evanston, IL J. Åkerman3,41. Argonne National Laboratory, Lemont, IL; 2. Northwestern University, Evanston, IL; 3. University of 9:30 Gothenburg, Gothenburg, Sweden; 4. Royal Institute of Technology, Kista, Sweden EH-06. The effects of Dzyaloshinskii-Moriya interaction on the ferromagnetic resonance response in nanosized devices. 10:42 K. Eason1, J. Kong1,2, C. Sim1, M. Tran1, J. Huang1, M. Sabino4,1, S. He3 and Z. Kho5,11. Advanced Concepts and Nanotechnology EH-12. Influence of noise on the gyrotropic motion of vortex Division, Data Storage Institute, Singapore, Singapore; 2. magnetization in spin transfer nano-oscillators. E. Grimaldi1, Physics, Massachusetts Institute of Technology, Cambridge, MA; P. Bortolotti1, A. Dussaux1, J. Grollier1, A. Fukushima2, 3. Physical & Mathematical Sciences, Nanyang Technological H. Kubota2, K. Yakushiji2, S. Yuasa2, V. Cros1 and A. Fert11. Unité University, Singapore, Singapore; 4. Electrical and Computer Mixte de Physique CNRS/Thales and Université Paris Sud, Engineering, National University of Singapore, Singapore, Palaiseau, France; 2. National Institute of Advanced Industrial Singapore; 5. Physics, National University of Singapore, Science and Technology, Tsukuba, Japan Singapore, Singapore 178 PROGRAM PROGRAM 179

γ 10:54 EP-04. Tuning Exchange Bias in Core/Shell Fe/ Fe2O3 Nanoparticles: Role of Frozen Interfacial and Surface Spins. H. Khurshid1, EH-13. Influence of the bias field orientation on the oscillation 1 1 1 M. Phan , P. Mukherjee and H. Srikanth 1. Department of behavior of spin torque oscillators having a perpendicularly Physics, University of South Florida, Tampa, FL magnetized free layer. S. Tamaru1, H. Kubota1, K. Yakushiji1, R. Matsumoto1, T. Nozaki1, A. Fukushima1, H. Imamura1, 1 1 1 T. Taniguchi , H. Arai and S. Yuasa 1. Spintronics Research EP-05. Exchange bias induced by the fully strained La2/3Ca1/3MnO3 Center, National Institute of Advanced Industrial Science and dead layers. Q. Xie1, X. Wu1, F. Zhang1, J. Gao2 and Q. Jia31. Technology (AIST), Tsukuba, Ibaraki, Japan Department of Physics, Nanjing University, Nanjing, China; 2. Department of physics, The University of Hong Kong, Hongkong, China; 3. Institute of High Energy Physics, Chinese Academy of 11:06 Sciences, Beijing, China EH-14. Synchronization in chains of spin transfer torque oscillators. 1 1 2 1 I. Volvach , M. Escobar , M. Lubarda and V. Lomakin 1. Center EP-06. Dynamic Exchange Bias Effect in for Magnetic Recording Research, University of California, San Ferromagnetic/Nonmagnetic/Anti-ferromagnetic Trilayer. Diego, La Jolla, CA; 2. Politechnics, University of Donja Gorica, L. Jin1,3, D. Zhang1,2, H. Zhang1, X. Tang1, F. Bai1, Z. Zhong1 and Podgorica, Montenegro J. Xiao31. State Key Laboratory of Electronic Thin Films and Integrated Devices, University of Electronic Science and 11:18 Technology of China, Chengdu, Sichuan, China; 2. Department of Electrical and Computer Engineering, University of Delaware, EH-15. Influence of the interlayer coupling on the spin torque driven Newark, DE; 3. Department of Physics and Astronomy, University 1 1 excitations in a STO. E. Monteblanco , M. Romera , F. Garcia- of Delaware, Newark, DE Sanchez1, C. Dieudonné1,2, D. Gusakova1, L.D. Buda-Prejbeanu1, M.C. Cyrille2 and U. Ebels11. SPINTEC, SPINTEC, UMR CEA / CNRS / UJF-Grenoble 1 / Grenoble-INP, INAC, Grenoble, F- EP-07. Unconventional Exchange Bias in Bismuth Ferrite 1 1 38054, France, Grenoble, France; 2. LETI, CEA-LETI, Nanoparticles. S.K. Srivastav and N.S. Gajbhiye 1. Chemistry, MINATEC-Campus, 17 Rue des Martyrs, 38054 Grenoble, Indian Institute of Technology, Kanpur, uttar Pradesh, India France, Grenoble, France EP-08. The interplay between exchange bias coupling and interlayer coupling in NiFe/CoO/Co trilayers. K. Lin1, T. Lan1, C. Shueh1 and J. van Lierop21. Department of Materials Science and Engineering, National Chung Hsing University, Taichung, THURSDAY EXHIBIT HALL Taiwan; 2. Department of Physics and Astronomy, University of MORNING Manitoba, Winnipeg, MB, Canada 9:30 EP-09. The Role of Inducing Magnetic Field on the Symmetry- Session EP Breaking of Perpendicular Exchange Bias Behavior in Co Pt /IrMn Bilayers. C. Tsai1, S. Padmanapan2,3, J. Hsu2 and EXCHANGE BIAS II 49 51 K. Lin11. Graduate Institute of Materials Science and (Poster Session) Engineering, National Taiwan University, Taipei, Taiwan; 2. Jose de la Venta, Chair Department of Physics, National Taiwan University, Taipei, Taiwan; 3. Defence Metallurgical Research Laboratory, Hyderabad, India EP-01. Positive exchange bias in [Pt/Co]3/IrMn multilayer. S. Yoon1, J. Kwon1, S. Lee1 and B. Cho11. School of Materials Science and Engineering, Gwangju Institute of Science and Technology, EP-10. Exchange Bias Magnetism in Films of NiFe/(Ni,Fe)O Gwangju, Republic of Korea Nanocrystallite Dispersions. C. Hsiao1, R. Desautels2, J. van Lierop2, K. Lin3, T. Lin1 and H. Ouyang11. National Tsing Hua University, HsinChu, Taiwan; 2. University of Manitoba, EP-02. Upper-interface exchange bias modulated by the lower Winnipeg, MB, Canada; 3. National Chung Hsing University, interface in ferromagnetic/antiferromagnetic/ferromagnetic Taichung, Taiwan trilayers. Y. Hu 1, F. Shi2, N. Jia1, Y. Liu1, H. Wu1 and A. Du11. College of Sciences, Northeastern University, Shenyang, China;

2. Physics Department, Auburn University, Auburn, AL EP-11. Exchange bias in melt spun Fe52-xMn23+xGa25 (x = 0-3) ribbons. C. Shih1, X.G. Zhao2, H.W. Chang3 and W.C. Chang11. Department of Physics, National Chung-Cheng university, Chia- EP-03. A study on the occurrence of positive exchange bias in the as- Yi, Taiwan; 2. Shenyang National Laboratory for Materials grown Co49Pt51/IrMn bilayers. C.Y. Tsai1, J. Hsu2, Science, Institute of Metal Research, Chinese Academy of P. Saravanan2 and K.F. Lin11. Graduate Institute of Materials Sciences, Shenyang, China; 3. Department of Applied Physics, Science & Engineering, National Taiwan Unviersity, Taipei, Tunghai University, Taichung, Taiwan Taiwan; 2. Physics, National Taiwan University, Taipei, Taiwan 180 PROGRAM PROGRAM 181

EP-12. In-phase and out-of-phase excitation of spin wave and NiFe EQ-03. Magnetic properties of polycrystalline and nanocrystalline 1 1 1 1 resonance modes in NiFe/IrMn bilayers. M.A. Sousa , NdMnO3 S. Chandra , A. Biswas , M.H. Phan and F. Pelegrini1, J. Quispe-Marcatoma2, W. Alayo3 and E. Baggio- H. Srikanth11. Department of Physics, University of South Saitovitch21. Instituto de Fisica, Universidade Federal de Goias, Florida, Tampa, FL Goiania, Goias, Brazil; 2. Centro Brasileiro de Pesquisas Fisicas, Rio de Janeiro, Rio de Janeiro, Brazil; 3. Departamento de EQ-04. Exploring the ferromagnetism in Sr0.25Y0.75CoO3-delta by Fisica, Universidade Federal de Pelotas, Pelotas, Rio Grande do magnetic and non-magnetic ion substitution at the cobalt Sul, Brazil sites.X. Yu2,1, Z. Wang1, L. Wang1, S. He2, X. Zheng1, R. Wu1, J. Sun1 and B. Shen11. State Key Laboratory for Magnetism, EP-13. Anisotropies in Exchange Bias Systems. R. Carpenter1, Beijing National Laboratory for Condensed Matter Physics, G. Vallejo-Fernandez1 and K. O’Grady11. Department of Physics, Institute of Physics, Chinese Academy of Sciences, Beijing, The University of York, Heslington, YO10 5DD, United Kingdom Beijing, China; 2. Department of Physics, Capital Normal University, Beijing, Beijing, China EP-14. Exchange bias in magnetite films made by Ion-beam assisted deposition. J. McCloy1,2, W. Jiang2, P. Gassman2, M. Kaur3, EQ-05. The magnetic and electronic structures in YTiO3/BaTiO3 Y. Qiang3, E. Burks4, K. Liu4 and F. Namavar51. School of superlattice.P. Zhou1, Z. Yan1 and J. Liu11. Department of Mechanical and Materials Engineering, Washington State Physics, Nanjing University, Nanjing, Jiangsu, China University, Pullman, WA; 2. Pacific Northwest National Laboratory, Richland, WA; 3. Physics, Idaho State University, EQ-06. Influence of lattice strain on charge/orbital ordering and Moscow, ID; 4. Physics, University of California Davis, Davis, phase separation in Pr (Ca Sr ) MnO thin CA; 5. University of Nebraska Medical Center, Omaha, NE 0.7 0.6 0.4 0.3 3 films.Y. Zhao1, J. Wang1, F. Hu1, H. Kuang1, R. Wu1, X. Zheng1, J. Sun1 and B. Shen11. Beijing National Laboratory for EP-15. Enhancement of perpendicular exchange bias in Pt/Co/α- Condensed Matter Physics and State Key Laboratory of α Cr2O3 thin film system by controlling crystalline quality of - Magnetism, Institute of Physics,CAS, Beijing, China 1 1 1 1 Cr2O3 layer. Y. Shiratsuchi , Y. Takechi , Y. Nakano , S. Onoue and R. Nakatani11. Osaka University, Osaka, Japan EQ-07. Electromagnetic properties of ferroelectric/ferromagnetic thin film heterostructures. D. Chen1,2, I. Harward1, K. Linderman1, 1 1,3 1 EP-16. Control of Morin transition of Fe2O3 (0001) thin film by E. Economou , Y. Nie and Z. Celinski 1. Center for Magnetism inducing strain and Ir doping. Y. Sato1, N. Shimomura1, and Magnetic Nanostructures, University of Colorado at T. Nozaki1 and M. Sahashi11. electronic engineering, Tohoku Colorado Springs, Colorado Springs, CO; 2. State Key University, Aoba-ku, Sendai, Miyagi, Japan Laboratory of Electronic Thin Films and Integrated Devices, University of Electronic Science and Technology of China, Chengdu, Sichuan, China; 3. School of Optical and Electronic Information, Huazhong University of Science and Technology, Wuhan, Hubei, China THURSDAY EXHIBIT HALL MORNING EQ-08. Oxygen Annealing Studies on SnO2:Co Thin Films Deposited 9:30 by RF Sputtering. G.M. Stoian1, P.A. Stampe2, R.J. Kennedy2, E. Lochner1, Y. Xin3 and S. von Molnar11. Physics, Florida State Session EQ University, Tallahassee, FL; 2. Physics, Florida A&M University, Tallahassee, FL; 3. National High Magnetic Field Laboratory, COMPLEX OXIDES Tallahassee, FL (Poster Session) Maria Varela, Chair EQ-09. Magnetic and magnetooptical properties of polycrystalline iron-substituted strontium titanate–iron nanocomposites. 1 1 1 1 1 EQ-01. Investigation of site preference of Zn doped Ba Co T. Goto , D. Kim , N. Aimon , X. Sun , C. Zhang and 3 2- 1 1 1 C.A. Ross 1. Massachusetts Institute of Technology, Cambridge, xZnxFe24O41 by Mössbauer spectroscopy. J. Lim , C. Rhee , H. Noh1 and C. Kim11. Physics, Kookmin University, Seoul, MA Republic of Korea

EQ-02. Enhanced multiferroicity in non-stoichiometric MnWO4.H. Yu1, M. Liu1, Z. Yan1, S. Dong2 and J. Liu11. Department of Physics, Nanjing University, Nanjing, Jiangsu, China; 2. Department of Physics, Southeast University, Nanjing, China 182 PROGRAM PROGRAM 183

EQ-10. Magnetically doped LaAlO3 Thin Films Grown on SrTiO3 for ER-02. Numerical Modeling in 2-D of Oriented Grain Si-Fe Magnetic Modified Quasi-Two-Dimensional Electron Gases. Steels. E. Cardelli1,2 and A. Faba1,21. University of Perugia, M.T. Gray1,2, T.D. Sanders3,4, F.J. Wong1,5, C.A. Jenkins6, Perugia, Italy; 2. Center for electric and magnetic applied E.A. Arenholz6 and Y. Suzuki1,41. Materials Science and research, University of Perugia, Perugia, Italy Engineering, Stanford University, Stanford, CA; 2. Materials Science and Engineering, University of California, Berkeley, CA; ER-03. Effect of Cold Rolling Direction on the Crystallographic 3. Applied Science and Technology Graduate Group, University of Texture and Magnetic Properties of Nonoriented Electrical California, Berkeley, CA; 4. Applied Physics, Stanford University, Steel. Y. He 1, E. Hilinski2, J. Li1, M. Attard1, D. Bibby1, Stanford, CA; 5. Materials Sciences Division, Lawrence Berkeley R. Santos1 and R. Zavadil11. Canmet Materials, Natural National Laboratory, Berkeley, CA; 6. Advanced Light Source, Resources Canada, Hamilton, ON, Canada; 2. Research and Lawrence Berkeley National Laboratory, Berkeley, CA Technology Center, United States Steel Corporation, Munhall, PA

EQ-11. Defect induced ferromagnetism in undoped ZnO ER-04. Magnetic Hysteresis Curve Influenced by Power- nanoparticles. K. Rainey1, J. Chess1, J. Eixenberger1, Semiconductor Characteristics in PWM Inverter. K. Fujisaki1 D.A. Hillsberry1, D.A. Tenne1, C. Hanna1 and A. Punnoose11. and S. Liu11. Toyota Technological Institute, Nagoya-city, Aichi- Physics, Boise State University, Boise, ID prefecture, Japan

EQ-12. Effect of the magnetic order on the optical properties of ER-05. Soft magnetic properties of polymer coated Fe powder cores Manganese-doped transparent oxide semiconductors. mixed with oxidized pure Fe and Fe-6.5 wt.% Si powders. Q. Shao1, X. Wang1, A. Ruotolo1, J. Antonio Zapien1,2 and E. Cha1 and H. Kim11. Korea Institute of Industrial Technology, C. Leung31. The Department of Physics and Materials Science, Incheon, Republic of Korea City University of Hong Kong, Kowloon, Hong Kong; 2. Center of Super-Diamond and Advanced Films (COSDAF), City University of Hong Kong, Kowloon, Hong Kong; 3. Department of Applied ER-06. Effect of disorder in the structural and magnetic properties of Physics and Materials Research Centre, Hong Kong Polytechnic the Fe50Si50 system. J.F. Piamba Jiménez1 and G.A. Pérez University, Hung Hom, Hong Kong Alcázar11. Physics, Universidad del Valle, Cali, Valle del Cauca, Colombia EQ-13. Metal-insulator and spin-state transition in polycrystalline

(Pr1-yREy)1-xCaxCoO3 (RE=rare earth elements) in magnetic ER-07. Prediction method of basic domain structure in Fe3%Si (110) fields. T. Naito1, H. Fujishiro1, T. Nishizaki2 and N. Kobayashi21. single crystal with grooved surface. K. Iwata1,4, M. Fujikura2, Iwate University, Morioka, Japan; 2. Institute for Materials S. Arai3 and K. Ishiyama41. Advanced Technology Research Research, Tohoku University, Sendai, Japan Laboratories, Nippon Steel & Sumitomo Metal, Futtsu, Japan; 2. Yawata R&D Laboratories, Nippon Steel & Sumitomo Metal, Kitakyushu, Japan; 3. Steel Research Laboratories, Nippon Steel EQ-14. Resistive switching in doped BiFeO3 films. L. Wu1, C. Jiang1 & Sumitomo Metal, Futtsu, Japan; 4. Research Institute of and D. Xue11. Key Laboratory for Magnetism and Magnetic Electrical Communication, Tohoku University, Sendai, Japan Materials of MOE, Lanzhou University,P. R. China., Lanzhou, Gansu,, China ER-08. Comparison of soft magnetic properties of casting-rolled plates with them of powder-rolled plates in the Fe-Si alloys. K. Hwang1, Y. Yoo1 and H. Kim11. Korea Institute of Industrial Technology, Incheon, Republic of Korea THURSDAY EXHIBIT HALL MORNING ER-09. High Saturation Magnetization in Fe-P soft magnetic alloy 9:30 achieved by a two-step heat-treatment.D. Prabhu1, S. Chandrasekhar1, V. Chandrasekharan1, G. Raghavan1 and Session ER K. Hono21. Centre for Automotoive Energy Materials, ARCI, India, Chennai, Tamil Nadu, India; 2. Magnetic Materials Unit, SOFT MAGNETIC STEELS AND ALLOYS National Institute for Materials Science, Tsukuba, Ibaraki, Japan (Poster Session) Vincent Sokalski, Co-Chair ER-10. Comparative study of structural and magnetic behavior of Josefina Silveyra, Co-Chair Fe1-xMx alloys (with x ≤ 6/32 and M = Al, Cr and Co). F. Reyes Gómez1, W. Aguirre Contreras1, G. Perez Alcazar1 and J. Tabares11. Fisica, Universidad del Valle, Santiago de Cali, ER-01. Magnetic properties of grain oriented electrical steel in model Valle del Cauca, Colombia transformer under DC-biased magnetization. H. Inoue1 and S. Okabe11. Steel Research Laboratory, JFE Steel Corporation, Kurashiki, Japan 184 PROGRAM PROGRAM 185

ER-11. Magnetic study of chromium-doped iron sulfide nanosheets. THURSDAY EXHIBIT HALL C. Lin1, K. Funtov2, S. Starchikov2, I. Lyubutin2, Y. Tseng1, 1 1 1 3,4 3 MORNING J. Lee , T. Hsu , H. Hsu , S. Ovchinnikov and I. Edelman 1. 9:30 Department of Applied Physics, National Pingtung University of Education, Pingtung, Taiwan; 2. Shubnikov Institute of Crystallography, Russian Academy of Sciences, Moscow, Russian Session ES Federation; 3. Kirensky Institute of Physics, Siberian Branch of VOLTAGE CONTROL OF ANISOTROPY, Russian Academy of Sciences, Krasnoyarsk, Russian Federation; MAGNETORESISTANCE I 4. Institute of Engineering Physics and Radioelectronics, Siberian Federal University, Krasnoyarsk, Russian Federation (Poster Session) Takayuki Nozaki, Chair ER-12. Thermomagnetic and magnetostrictive properties of 1 1 Fe81Ga19Tbx (x=0.3) textured alloy. T.I. Fitchorov , Y. Chen , ES-01. Voltage Tuning of Ferromagnetic Resonance with Bistable 1 2 2 2 1 S. Bennett , L. Jiang , G. Zhang , Z. Zhao and V.G. Harris 1. Magnetization Switching in Energy-Efficient Magnetoelectric Electrical and Computer Engineering, Northeastern University, Composites. Z. Zhou1, M. Liu2, T. Nan1, B. Howe2, G. Brown2 Boston, MA; 2. Baotou Research Institute of Rare Earths, Baotou, and N. Sun11. ECE, Northeastern University, Boston, MA; 2. Inner Mongolia, China Materials and Manufacturing Directorate, Air Force Research Laboratory, Wright-Patterson Air Force Base, OH

ER-13. Magnetic properties of the MnRu1-xRhxAs system under high pressure as well as in view of electronic band structure ES-02. Electric field induced changes in magnetoresistance and 1 2 3 1 calculations.D. Szymanski , J. Tobola , M. Guillot , R. Duraj , magnetic switching field of Co/Cu/Fe on BaTiO single crystal. 1 1 4 3 R. Zach , W. Chajec and D. Fruchart 1. Institute of Physics, H. Kojima1, Y. Hamasaki1, M. Itoh1 and T. Taniyama11. Materials Cracow University of Technology, ul. Podchorazych 1, 30-084 and Structures Laboratory, Tokyo Institute of Technology, Cracow, Poland; 2. AGH University of Science and Technology, Yokohama, Japan Al. Mickiewicza 30, 30-059 Cracow, Poland; 3. LNCMI, CNRS, BP 166,, 38-042 Grenoble cedex 9, France; 4. Institut Neel, CNRS, BP 166,, 38-042 Grenoble cedex 9, France ES-03. Non-volatile switching of ferromagnetic resonance in magnetoelectric composites for reconfigurable microwave devices. B. Howe1, M. Liu1 and G. Brown11. Air Force Research ER-14. Parallel Path Magnetic Technology for high temperature Lab, Wright-Patterson AFB, OH applications.J.M. Silveyra2,1 and M.E. McHenry11. Department of Materials Science and Engineering, Carnegie Mellon ES-04. Electric-field-induced ferromagnetic resonance in magnetic University, Pittsburgh, PA; 2. INTECIN, Faculty of Engineering, 1 1 1 University of Buenos Aires - CONICET, Buenos Aires, Argentina tunnel junctions. W. Skowronski , T. Stobiecki , J. Wrona , G. Reiss2 and S. van Dijken31. Department of Electronics, AGH University of Science and Technology, Krakow, Poland; 2. Thin ER-15. High-frequency rotational losses in different Soft Magnetic Films and Physics of Nanostructures, Bielefeld University, 1 2 3 Composites (SMC). O. de la Barrière , C. Appino , C. Ragusa , Bielefeld, Germany; 3. Department of Applied Physics, Aalto 2 1 1 F. Fiorillo , F. Mazaleyrat and M. LoBue 1. ens cachan, Cachan, University School of Science, Espoo, Finland France; 2. INRIM, Torino, Italy; 3. Politecnico di Torino, Torino, Italy ES-05. Room temperature ferromagnetism modulated by resistance

switching in Au/CeO2/PrBa2Cu3O7-x/Pt ER-16. Characterizing Local Anisotropy of Coercive Force in Motor heterostructure.Y. Chao1, Y. JinBo1, C. XueGang1, F. JianBo1, Laminations with the Moving Magnet Hysteresis Comparator. L. GuiJun1, X. GuangCheng1, Z. Yan1 and L. ShunQuan11. School 1 2 I.J. Garshelis and G. Crevecoeur 1. Magnova, Inc., Pittsfield, of Physics, Peking University, Beijing, China MA; 2. Department of Electrical Energy, Systems & Automation, Ghent University, B-9000 Ghent, Belgium ES-06. Electric-Field and Strain Control of Interface Magnetocrystaline Anisotropy in FePd-based films. P. Ong1, N. Kioussis1, P. Khalili Amiri2, J. Alzate2, K.L. Wang2 and G.P. Carman31. W. M. Keck Computational Materials Theory Center, California State University, Northridge, CA; 2. Department of Electrical Engineering, University of California, Los Angeles, CA; 3. Department of Mechanical and Aerospace Engineering, University of California, Los Angeles, CA

ES-07. Magnetic, Transport and Structural Properties of SrRuO3 Thin Films.K. Rode1, A.M. Majcher2,1, J. Coey1 and P.S. Stamenov11. Physics Department, School of Physics, Dublin, Dublin, Ireland; 2. Institute of Physics, Jagiellonian University, Krakow, Krakow, Poland 186 PROGRAM PROGRAM 187

ES-08. Magneto-transport properties of Co-Ir synthetic ferrimagnets THURSDAY EXHIBIT HALL with perpendicular magnetic anisotropy. J. Sharma1, 1 1 1 1 MORNING C.L. Melamed , S.K. Patel , C.J. Thompson , P.D. Sparks , 9:30 J.C. Eckert1, M. Gottwald2 and E.E. Fullerton21. Physics, Harvey Mudd College, Claremont, CA; 2. Center for Magnetic Recording Research, University of California, San Diego, La Jolla, CA Session ET ULTRA-THIN FILM MAGNETISM II ES-09. Hall effect study of Co/Ni multilayers. S.K. Patel1, (Poster Session) C.L. Melamed1, J. Sharma1, C.J. Thompson1, P.D. Sparks1, Jordi Sort, Co-Chair 1 2 2 2 J.C. Eckert , M. Gottwald , J.J. Kan and E.E. Fullerton 1. Gonzalo Vallejo-Fernandez, Co-Chair Physics, Harvey Mudd College, Claremont, CA; 2. Center for Magnetic Recording Research, University of California, San Diego, La Jolla, CA ET-01. Impact of Fluorine-based Reactive Chemistry on Structure and Properties of High Moment Magnetic Material.X. Yang1, L. Chen1, H. Han1, H. Fu1, M. Sun1, F. Liu1 and J. Zhang11. R&D ES-10. Focused ion beam fabrication and magneto-electrical RIE/CVD, Magnetic Head Operations, Western Digital, Fremont, transport properties of La0.67Ca0.33MnO3 CA Nanobridge.P. Li 1, Y. An1, D. Guo1, J. Xiao1 and W. Tang 11. School of Science, State Key Laboratory of Information Photonics & Optical Communication,Beijing University of Posts and ET-02. Influence of the interface on the magnetic properties of Telecommunications, Beijing,100876, China ferromagnetic ultrathin films with various adjacent copper thicknesses.D. Zhang1,2, S. Jiang1, C. Luo1, Y. Wang1, W. Rui3, Y. Zhai1,3, J. Du3 and H. Zhai31. Physics Department, Southeast ES-11. Anomalous Hall effect in ferromagnetic FeGa thin films University, Nanjing, China; 2. School of Physics Science and grown on GaSb (100) by MBE. A. Duong1, Y. Shin1 and Information Engineering, Liaocheng University, Liaocheng, S. Cho11. Physics, University of Ulsan, Ulsan, Republic of Korea China; 3. National Laboratory of Solid Microstructures, Nanjing University, Nanjing, China ES-12. Enhanced magnetoimpedance effect in patterned FeNi/FeCo nanostructure. J. Wang1, Y. Zhang1, X. Sun1 and Q. Liu11. Key ET-03. Effect of Ga+ irradiation in MBE grown Pt/Co/Pt thin films Laboratory for Magnetism and Magnetic Materials of Ministry of studied by magneto-optic spectroscopy. E.L. Jakubisova1, Education, Lanzhou, China S. Visnovsky1, A. Wawro2, L. Baczewski2, P. Mazalski3, A. Maziewski3, M. Liedke4, J. McCord4 and J. Fassbender41. ES-13. Skew scattering dominated anomalous Hall resistivity in Faculty of Mathematics and Physics, Charles University in 1 1 Co100-x(MgO)x granular thin films. Q. Zhang , Z. Guo , Prague, Prague, Czech Republic; 2. Institute of Physics, Polish B. Zhang1, R.O. Aboljadayel1, L. Li2, L. Chen2 and X. Zhang1,21. Academy of Sciences, Warszawa, Poland; 3. Department of Thinfilm Lab, Core labs, King Abdullah University of Science and Physics, University of Bialystok, Bialystok, Poland; 4. Institute of Technology (KAUST), Jeddah, Saudi Arabia; 2. Ion Beam Physics and Material Research, Research Helmholtz- Imaging&Characterization, Core labs, King Abdullah University Zentrum Dresden-Rossendorf, Dresden, Germany of Science and Technology (KAUST), Jeddah, Saudi Arabia ET-04. Thin and ultrathin Cobalt films on nanoporous substrates: ES-14. Anisotropic magnetothermopower and magnetotransport magnetometry and positron annihilation studies. P. Metaxas1, effects in Pt/Co/Pt layered structures.A. Frauen1, T. Böhnert1, P. Guagliardo2, V. Baltz3, C. Chang1, M. Kostylev1, S. Samarin2, A. Kobs1, A. Burgardt1, G. Winkler1, K. Nielsch1 and J.F. Williams2, X. Sun4, M. Lai4, A. Keating4, N. Oshima5, H. Oepen11. Institut für Angewandte Physik, Universität R. Suzuki5 and A. Uedono61. School of Physics, University of Hamburg, Hamburg, Germany Western Australia, Crawley, WA, Australia; 2. ARC Centre of Excellence for Antimatter-Matter Studies, School of Physics, University of Western Australia, Crawley, WA, Australia; 3. ES-15. Scaling of the Thickness dependent Anomalous Hall SPINTEC, UMR 8191, CEA-INAC/CNRS/UJF-Grenoble Conductivity in Amorphous ferromagnetic thin films. X. Fan1, 1/Grenoble-INP, Grenoble, France; 4. School of Mechanical and H. Chen1, J. Rao1 and D. Xue11. The Key Lab for Magnetism and Chemical Engineering, University of Western Australia, Crawley, Magnetic Materials of Ministry of Education, Lanzhou University, WA, Australia; 5. Research Institute of Instrumentation Frontier, Lanzhou, Gansu, China National Institute of Advanced Industrial Science and Technology, Tsukuba, Japan; 6. Division of Applied Physics, Faculty of Pure and Applied Science, University of Tsukuba, Tsukuba, Japan 188 PROGRAM PROGRAM 189

ET-05. Laser ablated Co2MnSi thin films grown on (001) SrTiO3 ET-14. Anisotropic spin structure along the easy axis of substrates. H. Pandey1, P.K. Rout1, P.C. Joshi1 and magnetization in epitaxially grown MnAs/GaAs(100) thin R.C. Budhani1,21. Condensed Matter-Low Dimensional Systems film. J. Song1,2, Y. Cui2, J. Lee2 and J.B. Ketterson21. Physics, Laboratory, Department of Physics, Indian Institute of Chungnam National University, Daejeon, Republic of Korea; 2. Technology, Kanpur, UP-208016, India; 2. National Physical Physics & Astronomy, Northwestern University, Evanston, IL laboratory, New delhi, 110012, India ET-15. Transformation Kinetics in Epitaxial FeRh Films. M. Loving1, 2 1 ET-06. Single crystal Fe1−xGax thin films for Monolithic Microwave C.H. Marrows and L.H. Lewis 1. Chemical Engineering, Devices. B.K. Kuanr1,2 and Z. Celinski11. Department of Physics, Northeastern University, Boston, MA; 2. Physics and Astronomy, University of Colorado at Colorado Springs, Colorado Springs, University of Leeds, Leeds, United Kingdom CO; 2. Electronics Department, Zakir Husain Delhi College (University of Delhi), Delhi, India ET-16. High mobility charge transport at magnetic Heusler alloy- 1 1 2 1 SrTiO3 interface. P.K. Rout , H. Pandey , L. Wu , .. Anupam , ET-07. Investigation of magnetization and magnetic anisotropy of P.C. Joshi1, Z. Hossain1, Y. Zhu2 and R.C. Budhani1,31.

tetragonal distorted FeCo alloy epitaxially grown on L10 FePt Department of Physics, Indian Institute of Technology Kanpur, film. B. Wang1, H. Oomiya1, A. Arakawa1, T. Hasegawa1 and Kanpur-208016, India; 2. Brookhaven National Laboratory, S. Ishio11. Department of Materials Science and Engineering, Upton-11973, NY; 3. CSIR-National Physical Laboratory, New Akita University, Akita, Japan Delhi-110012, India

ET-08. Nonlinear strain dependence of magnetic anisotropy in ET-17. Hall effect detection of optically invisible defects in CVD 1 1 1 1 1 1 1 CoFe2O4 films. M. Tanaka , K. Harada , M. Takemura , K. Mibu graphene. D.H. Petersen , B.S. Jessen , F. Pizzocchero , and J. Inoue21. Nagoya Institute of Technology, Nagoya, Japan; 2. D. Kjær2,1, H.H. Henrichsen1,2, O. Hansen1,3 and P. Bøggild11. University of Tsukuba, Tsukuba, Japan DTU Nanotech, Technical University of Denmark, Kgs. Lyngby, Denmark; 2. Capres A/S, Kgs. Lyngby, Denmark; 3. CINF, Technical University of Denmark, Kgs. Lyngby, Denmark ET-09. FeNiSiB/CoFeB/MgO composite ferromagnetic thin films exhibiting perpendicular magnetic anisotropy. J. Choi11. Department of Materials Science and Engineering, Korea University, Seoul, Republic of Korea THURSDAY EXHIBIT HALL ET-10. Non-orthogonal magnetic configurations in MORNING CoFeB/Pt/Ru/Pt/Co ferrimagnets. A. Fernandez-Pacheco1, F.C. Ummelen2, R. Mansell1, D. Petit1, J.H. Lee1, H.M. Swagten2 9:30 and R.P. Cowburn11. University of Cambridge, Cambridge, United Kingdom; 2. Department of Applied Physics, Center for Session EU NanoMaterials, Eindhoven University of Technology, Eindhoven, MAGNETIZATION DYNAMICS: ULTRAFAST Netherlands DYNAMICS AND SPIN WAVES (Poster Session) ET-11. Tuning the perpendicular magnetic anisotropy in ultrathin MgO/CoFeB/Ta by controlling the Ta thickness. C. Cheng1, Marco Battiato, Chair S. Shen1 and G. Chern11. Department of Physics, National Chung Cheng University, Chia-Yi, Taiwan EU-01. Measurements of Dzyaloshinskii-Moriya interaction by propagating spin wave spectroscopy. H. Hata1, R. Hiramatsu1, 1 1 1 2 2 ET-12. Effect of low-frequency alternative-current magnetic T. Taniguchi , K. Kim , T. Moriyama , T. Koyama , D. Chiba , J. Moon3, K. Lee3,4 and T. Ono11. Institute for Chemical Research, susceptibility in CoFeB/MgOx/CoFeB magnetic tunnel junctions. Y. Chen1 and S. Lin11. Department of Materials Kyoto University, Uji, Kyoto, Japan; 2. Department of Applied Science and Engineering, I-Shou University, Kaohsiung Taiwan Physics, The University of Tokyo, Tokyo, Japan; 3. Department of 840, R.O.C., Kaohsiung, Taiwan Materials Science and Engineering, Korea University, Seoul, Republic of Korea; 4. KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul, Republic of ET-13. Realizing a High Magnetic Moment in Gd/Cr/FeCo: The Role Korea of the Rare Earth. C. Ward1, G. Scheunert1, W.R. Hendren1, R. Hardeman2, M.A. Gubbins2 and R.M. Bowman11. Queen’s University Belfast, Belfast, Antrim, United Kingdom; 2. Seagate EU-02. Unexpected double magnetic resonance in single crystal Ni on 1 1 Technology, Springtown, Londonderry, United Kingdom MgO: Anisotropy and thermal effects. M. Sinko , D. Stanley , B. Kaster1, M.J. Pechan1, C.A. Ross2, G. Kim2 and C.V. Thompson21. Physics, Miami University, Oxford, OH; 2. Materials Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA 190 PROGRAM PROGRAM 191

EU-03. A novel micromagnetic simulation approach to determine EU-10. Micromagnetic simulations of spin-wave normal modes and dispersion relations in magnonic crystals. B. Van de Wiele1, the spin-transfer-torque driven magnetization dynamics of a F. Montoncello2 and A. Vansteenkiste31. Department of Electrical ferromagnetic cross.T. Pramanik1, U. Roy1, M. Tsoi2, Energy, Systems and Automation, Ghent University, Ghent, L. Register1 and S. Banerjee11. Microelectronics Research Center, Belgium; 2. Dipartimento di Fisica e Scienze della Terra, University of Texas at Austin, Austin, TX; 2. Department of Universita degli Studi di Ferrara, Ferrara, Italy; 3. Department Physics, University of Texas at Austin, Austin, TX of Solid State Sciences, Ghent University, Ghent, Belgium EU-11. High-energy spin waves at metal/metal interfaces. EU-04. Magnetic properties and fast magnetization dynamics for R. Jayaraman1, H. Ibach1 and C.M. Schneider11. Peter Grünberg MnAlGe epitaxial films with a perpendicular magnetic Institut, Forschungszentrum Jülich, Jülich, Germany anisotropy. S. Mizukami1, A. Sakuma2, A. Sugihara1, Y. Kondo1 and T. Miyazaki11. WPI-AIMR, Tohoku University, Sendai, Japan; EU-12. Influence of hot electrons on the ultrafast quench of 2. Dept. of Appl. Phys., Tohoku University, Sendai, Japan magnetization in Ni. M. Lüttich1, J. Walowski1, A. Mann1, M. Münzenberg1, U. Atxitia2 and O. Chubykalo-Fesenko21. I. EU-05. Phonon-magnon interactions in BCC iron: A combined Physikalisches Institut, Georg-August-Universität Göttingen, molecular and spin dynamics study. D.N. Perera1, Göttingen, Niedersachsen, Germany; 2. Instituto de Ciencia de D.P. Landau1, D.M. Nicholson2, G. Stocks2, M. Eisenbach2, Materiales de Madrid, Madrid, Spain J. Yin2 and G. Brown31. Center for Simulational Physics, The University of Georgia, Athens, GA; 2. Oak Ridge National EU-13. Line shape of spin-torque diode signals on dc bias and r.f. Laboratory, Oak Ridge, TN; 3. Florida State University, power. T. Yu1, H. Naganuma1, M. Oogane1 and Y. Ando11. Tallahassee, FL Department of Applied Physics, Tohoku university, Sendai, Japan

EU-06. Characterisation of Rare Earth-Transition Metal films for All- EU-14. Dipolar field effects on the critical current for spin transfer Optical Magnetic Recording. C.M. Forbes1, W.R. Hendren1, switch of iron and permalloy nanoelements.A.L. Dantas1, I. Radu2 and R.M. Bowman11. Queen’s University Belfast, J.M. Araújo2, I.S. Queiroz Jr.3, G.O. Rebouças3 and Belfast, United Kingdom; 2. Helmholtz-Zentrum Berlin, Berlin, A.S. Carriço21. Departament of Physics, University of State of Rio Germany Grande do Norte, Mossoró, RN, Brazil; 2. Department of Physics, Universidade Federal do Rio Grande do Norte, Natal, RN, Brazil;

EU-07. Effects of Defect Types on the Dynamic Behavior of Ni80Fe20 3. Department of Physics, Universidade Federal Rural do Semi- Nanowires. J. Ding1, M.G. Cottam2 and A.O. Adeyeye11. Arido, Mossoró, RN, Brazil Department of Electrical and Computer Engineering, National University of Singapore, Singapore, Singapore; 2. Department of EU-15. Electric field induced modulation of the ferromagnetic Physics & Astronomy, University of Western Ontario, London, resonance in magnetic tunnel junctions. Y. Lv 1, H. Zhao1, ON, Canada X. Chao1, M. Jamali1 and J. Wang11. Department of Electrical and Computer Engineering, University of Minnesota, EU-08. Element-selective ultrafast magnetization dynamics with an Minneapolis, MN extreme ultraviolet tabletop source. E. Turgut1, P. Grychtol1, C. La-O-Vorakiat1, J.M. Shaw2, R. Adam4, D. Rudolf4, EU-16. Size-dependent resonant excitation of magnetic nano-sphere H.T. Nembach2, T.J. Silva2, S. Mathias3, M. Aeschlimann3, particles of three-dimensional magnetic vortex.J. Lee1, C.M. Schneider4, H.C. Kapteyn1 and M.M. Murnane11. Physics, M. Yoo1, D. Han1, H. Lee1 and S. Kim11. National Creative University of Colorado, Boulder, Boulder, CO; 2. Research Initiative Center for Spin Dynamics and Spin-Wave Electromagnetics Division, National Institute of Standards and Devices, and Research Institute of Advanced Materials, Technology, Boulder, CO; 3. Research Center OPTIMAS, Department of Materials Science and Engineering, Seoul Natl. University of Kaiserslautern, Kaiserslautern, Germany; 4. Peter Univ., Seoul, Republic of Korea Grünberg Institut PGI-6 & JARA-FIT, Research Centre Jülich, Jülich, Germany

EU-09. Frequency noise in magnetic tunnel junction based spin torque oscillators.R. Sharma2, P. Dürrenfeld1, E. Iacocca1, J. Åkerman1,3 and P.K. Muduli1,21. Department of Physics, University of Gothenburg, Gothenburg, Sweden; 2. Department of Physics, Indian Institute of Technology, New Delhi, India; 3. Materials Physics, School of ICT, KTH-Royal Institute of Technology, Stockholm, Sweden 192 PROGRAM PROGRAM 193

THURSDAY EXHIBIT HALL EV-07. Study of sintered Nd-Fe-B magnets by TbHx nanoparticles grain boundary diffusion.C. Chang1, D. Zhang1, Y. Liu1, MORNING 1 1 9:30 M. Yue and J. Zhang 1. Beijing University of Technology, Beijing, China Session EV EV-08. Magnetic properties of PLD-fabricated isotropic Pr-Fe-B PERMANENT MAGNET PROCESSING I thick-film magnets applied for magnetic micro- (Poster Session) machines.M. Nakano1, S. Ohshima1, T. Yanai1 and Melania Marinescu, Chair H. Fukunaga11. Nagasaki university, Nagasaki, Japan

EV-01. Double coating protection of Nd-Fe-B magnets by EV-09. Enhancement in thickness of Nd-Fe-B thick-film magnets intergranular phosphating treatment and copper deposited on Si substrates by using a PLD 1 1 1 1 plating.J. Zheng1, L. Qiao1, M. Lin2, Y. Ying1, L. Jiang1 and method.M. Nakano , M. Oryoshi , T. Yanai and H. Fukunaga 1. S. Che11. College of Chemical Engineering and Materials Nagasaki University, Nagasaki, Japan Science, Zhejiang University of Technology, Hangzhou, Zhejiang, China; 2. Key Laboratory of Magnetic Materials and Devices, EV-10. Improvement of the thermal stability of sintered Nd-Fe-B Ningbo Institute of Material Technology & Engineering Chinese 1,2 magnets by intergranular addition of Dy82.3Co17.7 X. Zhang , Academy of Science, Ningbo, Zhejiang, China S. Guo1,2, R. Chen1,2, D. Lee3 and A. Yan1,21. Key Laboratory of Magnetic Materials and Devices, Ningbo Institute of Materials EV-02. Optimization of Magnetic Properties of Sintered (SmGdDyPr) Technology and Engineering, Chinese Academy of Sciences, (Co,Fe,Cu,Zr)z Magnets by Liquid Phase Sintering. L. Liu1,2, Ningbo, Zhejiang, China; 2. Zhejiang Province Key Laboratory of Z. Liu1,2, R. Chen1,2, X. Liu1,2, A. Yan1,2, D. Lee1,2 and W. Li1,21. Magnetic Materials and Application Technology, Ningbo Institute Key Laboratory of Magnetic Materials and Devices, Ningbo of Materials Technology and Engineering, Chinese Academy of Institute of Material Technology and Engineering, CAS, Ningbo, Sciences, Ningbo, Zhejiang, China; 3. University of Dayton, Zhejiang, China; 2. Zhejiang Province Key Laboratory of Dayton, OH Magnetic Materials and Application Technology, Ningbo Institute of Material Technology and Engineering, CAS, Ningbo, Zhejiang, EV-11. Structure and Magnetic Properties of Ba1-xLaxFe12O19 China 1 1 1 Prepared by Ba1-xLaxFe12O19S. Verma , P. Sharma , O. Pandey and A. Paesano Jr.21. School of Physics and Materials Science, EV-03. Regeneration of waste Nd-Fe-B sintered magnets doped with Thapar University, Patiala, India; 2. Departamento de Fisica, rare earth rich alloys.C. Li1, W. Liu1, M. Zakotnik1, Y. Liu1, Universidade Estadual de Maringá, Maringá, Parana, Brazil M. Yue1 and D. Zhang11. Beijing University of Technology, Beijing, China EV-12. Effects of microstructures of alloy ingot and strip casting alloy on the coercivity and anisotropy of HDDR-processed powders. 1 1 1 2 1 EV-04. Origin of radical coercivity reduction in fine Nd-Fe-B-type L. Cai , S. Guo , R. Chen , D. Lee and A. Yan 1. Ningbo Institute HDDR Particles and its recovery. H. Kwon1, L. Jung Gu2 and of Materials Technology & Engineering, Chinese Academy of Y. Ji Hoon31. Pukyong National University, Busan, Republic of Sciences, Ningbo, China; 2. University of Dayton, Dayton, OH Korea; 2. KIMS, Changwon, Republic of Korea; 3. KIMS, Changwon, Republic of Korea EV-13. Relation of microstructure and magnetic properties of shock wave compressed NdFeB magnets. M. Zhu1, Y. Li1,3, H. Feng1, 1 1 2 2 3 3 EV-05. Coercivity enhancement and elements distribution of sintered D. Zhou , W. Li , F. Lu , L. Chen , Y. Qi and A. Du 1. Division of Nd-Fe-B magnet by chemical bath deposition. S. Guo1, Functional Materials, Central Iron and Steel Research Institute, X. Zhang1, J. Di1, R. Chen1, D. Lee2,1 and A. Yan11. Zhejiang Beijing, China; 2. State Key Laboratory of Explosion Science and province Key Laboratory of Magnetic Materials and Application Technolog, Beijing Institute of Technology, Beijing, China; 3. Technology; Key Laboratory of Magnetic materials and Devices, College of Science, Northeastern University, Shenyang, China Ningbo Institute of Materials Technology and Engineering, Chiense Academy of Sciences, Ningbo, Zhejiang, China; 2. EV-14. Nd-Fe-B magnet blocks with high coercivity and reduced University of Dayton, Dayton, OH heavy rare earth element content. M. Marinescu1, C. Chinnasamy1, B. Cui1 and J. Liu11. Electron Energy Corp., EV-06. Optimization of the post-sintering annealing condition for the Landisville, PA high Cu content Nd-Fe-B sintered magnet. T. Kim1, S. Lee1, 2 3 3 H. Kim , M. Lee and T. Jang 1. Materials Science and EV-15. Coercivity enhancement of hydrogenation-disproportionation- Engineering, Korea University, Seoul, Republic of Korea; 2. R&D desorption-recombination processed Nd-Fe-B powders by the Center, Jahwa Electronics Co. Ltd., Cheongwon, Republic of diffusion of Al-Nd eutectic alloys. Z. Chao1, A. Sun1, S. Wu1, Korea; 3. Hybrid Engineering, Sunmoon University, Asan, J. Yang1 and J. Dong11. University of Science and Technology Republic of Korea Beijing, Beijing, China 194 PROGRAM PROGRAM 195

EV-16. Research on anisotropic bonded NdFeB magnets by 2-step EW-06. Magnetic nanoparticles for effective extraction of genomic compaction process. J. Dong1, A. Sun1, S. Wu1, C. Zou1 and DNAs.J. Min1, H. Cho1, J. Jang3, J. Wu2, C. Lim3 and Y. Kim11. J. Yang11. School of materials science and engineering, Material Science and Engineering, Korea University, Seoul, University of Science and Technology Beijing, Beijing, China Republic of Korea; 2. Pioneer Research Center for Biomedical Nanocrystals, Seoul, Republic of Korea; 3. College of Medicine, Korea University Guro Hospital, Seoul, Republic of Korea

EW-07. Comparative analysis of endocytic capacities to THURSDAY PLAZA BALLROOM A superparamagnetic iron oxide nanoparticles between different MORNING carcinoma cells via magnetophoresis. C. Huang1, T. Ger1, 9:30 M. Lai2, K. Hu2, Y. Peng3 and P. Fu11. Department of Power Mechanical Engineering, National Tsing Hua University, Session EW Hsinchu, Taiwan; 2. Institute of NanoEngineering and MicroSystems, National Tsing Hua University, Hsinchu, Taiwan; NANOPARTICLES: MEASUREMENTS AND 3. Institute of Biomedical Engineering, National Tsing Hua BIO APPLICATIONS University, Hsinchu, Taiwan (Poster Session) Hao Zeng, Chair EW-08. Microcrystal-like cellulose fibrils as the diamagnetic director for micro fluidic systems. Y. Miyashita1,2, M. Iwasaka1,3 and T. Kimura41. Graduate School of Engineering, Chiba University, EW-01. Nearly collective thermal relaxation and giant specific Chiba, Japan; 2. JSPS Research Fellow, Tokyo, Japan; 3. JST absorption rate of interacting superparamagnetic particles PRESTO, Saitama, Japan; 4. Graduate School of Agriculture, 1,2 2 2 ferrofluids.S.S. Pedrosa , A.L. Dantas , C.M. Souza , Kyoto University, Kyoto, Japan L.L. Oliveira1 and A.S. Carriço11. Department of Physics, Universidade Federal do Rio Grande do Norte, Natal, RN, Brazil; 2. Department of Physics, University of State of Rio Grande do EW-09. AC susceptibility response of magnetic fluids modulated by 1 1 Norte, Mossoró, RN, Brazil isolated- and chain-like particle morphology. L. He , M. Zhou , J. Zhong1, X. Peng1 and P.C. Morais1,21. Huazhong University of Science and Technology, Wu Han, China; 2. Universidade de EW-02. Controlling Temperature in Magnetic Hyperthermia with low Brasília, Brasília, Brazil Curie Temperature Nanoparticles.I. Astefanoaei1, I. Dumitru1, A. Stancu1 and H. Chiriac21. Faculty of Physics, Alexandru Ioan Cuza University, Iasi, Romania; 2. Magnetic Materials EW-10. SmFeN-Magnetic Silicone Rubber for Artificial Muscle. 1 1 1 1 Department, National Institute of Research & Development for T. Fukushi , S. Kim , S. Hashi and K. Ishiyama 1. Research Technical Physics, Iasi, Romania Institute of Erectrical Communication, Tohoku university, Sendai, Japan

EW-03. Synthesis, inductive heating, and magnetoimpedance-based detection of multifunctional Fe O nanoconjugates. EW-11. Magnetic loop shift in iron oxide nanoparticles coated with 3 4 1 2 3 J. Devkota1, K. Stojak1, J. Wingo1, T.T. Mai T2, P.T. Ha2, silica and gold. L.E. Woodard , C.L. Dennis , S. Lacerda , 1 4,1 5 H.N. Pham2, X.P. Nguyen2, P. Mukherjee1, H. Srikanth1 and P. Searson , M. Pomper and R. Ivkov 1. Institute for M. Phan11. Department of Physics, University of South Florida, NanoBioTechnology, Johns Hopkins University, Baltimore, MD; Tampa, FL; 2. Institute of Materials Science, Vietnam Academy of 2. National Institute of Standards and Technology, Gaithersberg, Science and Technology, Cau Giay, Hanoi, Viet Nam MD; 3. Food and Drug Administration, Bethesda, MD; 4. Radiology, Johns Hopkins University, Baltimore, MD; 5. Radiation Oncology, Johns Hopkins University, Baltimore, MD EW-04. Methotrexate Conjugated Magnetic Nanoparticle for Targeted Drug Delivery and Thermal Therapy. J. Gupta1 and D. Bahadur11. Metallurgical Engineering and Materials Science, EW-12. Spatial error distributions of magnetic nanoparticles using 1 1 Indian Institute of Technology Bombay,, Mumbai, Maharasthra, magnetorelaxometry noise data. A. Coene , G. Crevecoeur , 2 2 1 2 India M. Liebl , F. Wiekhorst , L. Dupré and U. Steinhoff 1. Department of Electrical Energy, Systems and Automation, Ghent University, Ghent, Belgium; 2. Physikalisch-Technische γ EW-05. Monodisperse water-soluble -Fe2O3/PVP nanoparticles for a Bundesanstalt, Berlin, Germany MRI contrast agent.D. Li1, J. Jiang1, Y. Zhang2, W. Gong1, J. Wang1, S. Ma1, W. Liu1 and Z. Zhang11. institute of metal research, Shenyang, Liaoning, China; 2. College of EW-13. Rotational Magnetic Hysteresis and Core Loss Measurement 1 2 Pharmaceutical Engineering, Shenyang Pharmaceutical of the Soft Magnetic Composite Materials. Y. Li , Q. Yang , 3 3 1 1 University, Shenyang, Liaoning, China Z. Lin , J. Zhu , Y. Wang and W. Yan 1. Hebei University of Technology, Tianjin, China; 2. Tianjin Polytechnic University, Tianjin, China; 3. University of Technology, Sydney, Sydney, NSW, Australia 196 PROGRAM PROGRAM 197

EW-14. Magnetic flux micro-sources for applications in biology. D. Le EX-06. Low loss NiZnCo ferrite based on hydrothermal method for Roy1, D. Mitrossilis2, L. Zanini1, F. Dumas-Bouchiat1,3, antenna application.K. Chen1, L. Jia1, X. Yu1 and H. Zhang11. D. Givord1, N. Dempsey1 and E. Farge21. Institut Néel, CNRS, University of Electronic Science and Technology of China, Grenoble, France; 2. Institut Curie, Paris, France; 3. SPCTS, Chengdu, China CNRS, Limoges, France EX-07. Grain growth, densification and gyromagnetic properties of

EW-15. Broadband magnetic resonance characterization of magnetite LiZnTi ferrites with H3BO3-Bi2O3-SiO2-ZnO glass addition. and Tb-doped magnetite nanocrystals. S.E. Russek1, C.T. Zhou1, W.H. Zhang1, J.L. Jia1, J. Li1, H. Su1, L.Y. Liu1, R.J. Usselman1, .P. Rice1, E.R. Evarts1, R. Geiss1, H.T. Nembach1 C.L. Jin1 and B.Y. Ma11. Electronic Information Materials and and T.J. Silva11. Natl Inst of Standards & Tech, Boulder, CO Components, State key laboratory of Electronic Thin Films and Integrated Devices, Chengdu, Sichuan, China

EX-08. Composition, microstuctures and magnetic properties of Bi- modified NiCuZn-ferrite for LTCC application.S. Zhang1, THURSDAY PLAZA BALLROOM A L. Jia1, J. Li1 and H. Zhang11. University of Electronic Science MORNING and Technology of China, Chengdu, China 9:30 EX-09. Magnetic properties and optical absorption of tunable narrow Session EX bandgap (CdMn)Fe2O4 ferrite thin films. S. Bennett1,2, SPINELS FOR HIGH FREQUENCY Y. Chen1,2, B. Assaf3, D. Heiman3 and V.G. Harris1,21. Center for Microwave Magnetic Materials and Integrated Circuits, APPLICATIONS Northeastern, Boston, MA; 2. Department of Electrical and (Poster Session) Computer Engineering, Northeastern University, Boston, MA; 3. Leonard Spinu, Chair Department of Physcs, Northeastern University, Boston, MA

EX-01. Structural, electrical and magnetic study of Ni0.5CdxFe2.5-xO4 spinel nanoferrites. A. Thakur1, P. Thakur1 and J. Hsu21. School of Physics, Shoolini University, Solan (HP)-173229, India; 2. THURSDAY PLAZA BALLROOM BC Department of Physics, National Taiwan University, Taipei 106, Taiwan AFTERNOON 1:30

EX-02. Mössbauer spectroscopy, magnetic characteristics and Session FA microwave analysis of Co1-xNix/2Srx/2Fe2O4 ferrite nanoparticles.A. Ghasemi1, A. Paesano Jr.2, X. Liu1 and SYMPOSIUM ON SPIN HALL AND RASHBA A. Morisako11. Shinshu University, Nagano, Japan; 2. EFFECTS IN MAGNETIC BILAYERS Universidade Estadual de Maringá, Marinag, Brazil Chia-Ling Chien, Chair

EX-03. Temperature dependence of the cubic magnetocrystalline 1:30 anisotropy constant of nanoparticulate powders of 1 2 Mg0.6Zn0.4Fe2O4 mixed ferrites. A. Franco Jr , F.A. Machado , FA-01. Spin Transfer Torque Arising from the Spin Hall Effect. 1 2 M.S. Santos and G.F. Barbosa 1. Instituto de Física, (Invited) L. Liu1, C. Pai1, A. Mellnik1, Y. Li1, H. Tseng1, O. Lee1, Universidade Federal de Goiás, Goiânia, Goiás, Brazil; 2. L. Leao1, M. Nguyen1, R.A. Buhrman1 and D. Ralph11. Cornell Departamento de Física, Universidade Federal de Pernambuco, University, Ithaca, NY Recife, Pernambuco, Brazil

2:06 EX-04. Bi2O3 liquid phase assisted improved magnetic characteristics of Mn-Ni-Cu-Zn ferrite nanoparticles for FA-02. Vector measurements of spin-orbit torques in ferromagnetic 1 MLCI application. S.E. Shirsath1, Y. Yasukawa1, X. Liu1 and heterostructures. (Invited) P. Gambardella 1. Dept. of Materials, A. Morisako11. Department of Information Engineering, Shinshu ETH, Zurich, Switzerland University, Nagano, Japan

EX-05. Preparation and characterization of NiCuZn ferrite sheets with Co substituted for 13.56MHz RFID communication.S. Yan1, W. Liu1, Z. Chen1, Y. Nie1, X. Wang1 and Z. Feng11. Huazhong University of Science and Technology, Wuhan, China 198 PROGRAM PROGRAM 199

2:42 2:54 FA-03. Observation of the nonlocal spin-orbital effective field. FB-04. Nanoscale spin reversal following ultrafast laser excitation in (Invited) X. Fan1, J. Wu1, H. Celik1, Y. Chen1, M.J. Jerry1, ferrimagnetic GdFeCo using x-ray diffraction. C.E. Graves1,2, H. Zhang2, V.O. Lorenz1 and J.Q. Xiao11. Department of Physics A.H. Reid2,3, B. Wu1,2, T. Wang2,4, S. de Jong2, I. Radu3, and Astronomy, Univ Delaware, Newark, DE; 2. State Key M. Messerschmidt2, R. Coffee2, M. Bionta2, S. Epp5, Laboratory of Electronic Films and Integrated Devices, R. Hartmann6, A. Tsukamoto7, J.J. Turner2, W.F. Schlotter2, University of Electronic Science and Technology of China, Y. Acremann8, A. Kimel3, A. Kirilyuk3, T. Rasing3, J. Stöhr2, Chengdu, Sichuan, China A. Scherz2 and H. Dürr21. Applied Physics, Stanford University, Stanford, CA; 2. SLAC National Accelerator Laboratory, Menlo Park, CA; 3. Institute for Molecules and Materials, Radboud 3:18 University Nijmegen, Nijmegen, Netherlands; 4. Materials FA-04. Spin Hall and Rashba effects in magnetic bilayers. (Invited) Science and Engineering, Stanford University, Stanford, CA; 5. P.M. Haney1, K. Kim2, H. Lee2, K. Lee3,4, A. Manchon5 and Advanced Study Group, CFEL, Hamburg, Germany; 6. PNSensor, M.D. Stiles11. Center for Nnanoscale Science and Technology, München, Germany; 7. Electronics and Computer Science, Nihon NIST, Gaithersburg, MD; 2. PCTP and Department of Physics, University, Chiba, Japan; 8. Laboratory for Solid State Physics, Pohang University of Science and Technology, Kyungbuk, ETH Zürich, Zürich, Switzerland Republic of Korea; 3. Department of Material Science & Engineering, Korea University, Seoul, Republic of Korea; 4. 3:06 Maryland Nanocenter, Univeristy of Maryland, College Park, MD; 5. Core Labs, King Abdullah University of Science and FB-05. Ultrafast and layer-selective magnetization dynamics in Technology, Thuwal, Saudi Arabia magnetic multilayers probed on a tabletop in the extreme ultraviolet range. P. Grychtol1, E. Turgut1, C. La-O-Vorakiat1, J. Shaw4, R. Adam3, D. Rudolf3, H. Nembach4, T. Silva4, 3:54 S. Mathias2, M. Aeschlimann2, C.M. Schneider3, H.C. Kapteyn1 FA-05. Spin orbit torques in Ta|CoFeB|MgO magnetic and M.M. Murnane11. Physics and JILA, University of Colorado, heterostructures. (Invited) M. Hayashi11. National Intsitute for Boulder, CO; 2. Physics, University of Kaiserslautern and Materials Science, Tsukuba, Japan Research Center OPTIMAS, Kaiserslautern, Germany; 3. Peter Grünberg Institut PGI-6 & JARA-FIT, Research Center Jülich, Jülich, Germany; 4. Electromagnetics Division, National Institute of Standards and Technology, Boulder, CO

THURSDAY PLAZA BALLROOM F 3:18 AFTERNOON FB-06. Orbital-resolved Spin Model for Thermal Magnetization 1:30 Switching in Rare-Earth-Based Ferrimagnets.S. Wienholdt1, D. Hinzke1, K. Carva2, P.M. Oppeneer2 and U. Nowak11. Physics Session FB Department, University of Konstanz, Konstanz, Germany; 2. ULTRAFAST DYNAMICS Department of Physics and Astronomy, Uppsala University, Hans Nembach, Chair Uppsala, Sweden

3:30 1:30 FB-07. Modeling demagnetization dynamics of magnetic alloys and FB-01. From the discovery to the control of THz spin currents: 1 1 1 multilayers. L. Xu towards ultrafast spintronics. (Invited) M. Battiato 1. and S. Zhang 1. University of Arizona, Department of Physics and Astronomy, Uppsala University, Tucson, AZ Uppsala, Sweden 3:42 2:06 FB-08. Influence of the magnetic domain structure on the laser induced ultrafast magnetization dynamics in [Co/Pd]n FB-02. The physics of spin transfer torque on the ultimate 1,2 2 3 1 1 1 multilayers. G. Malinowski , N. Moisan , B. Vodungbo , timescale.(Invited) A.J. Schellekens , K. Kuiper , R. de Wit and 3 3 2 1 B. Koopmans11. Applied Physics, TU/e, Eindhoven, Noord- B. Tudu , J. Luning , M. Hehn and A. Thiaville 1. Université Brabant, Netherlands Paris-sud, Laboratoire de Physique des Solides, CNRS UMR 8502, Orsay, France; 2. Université de Lorraine, Institut Jean Lamour, CNRS UMR 7198, Nancy, France; 3. Laboratoire de 2:42 Chimie Physique Matière et Rayonnement, Université Pierre et Marie Curie, CNRS UMR 7614, Paris, France FB-03. Controlling the precession of the magnetization in Nickel films using acoustic pulses generated by femtosecond laser pulses. J. Kim1, M. Vomir1 and J. Bigot11. IPCMS, DON., CNRS, Strasbourg, Bas-Rhin, France 200 PROGRAM PROGRAM 201

3:54 2:18 FB-09. Finite size simulations of linear reversal in FePt with an FC-03. Temperature-driven evolution of antiferromagnetic domains atomistic spin model. M.O. Ellis1, R.F. Evans1 and in FeRh thin films.C. Baldasseroni1, C. Antonakos2, C. Bordel3, R.W. Chantrell11. Dept. of Physics, University of York, York, A. Scholl4 and F. Hellman31. Department of Materials Science United Kingdom and Engineering, University of California Berkeley, Berkeley, CA; 2. Department of Chemistry, University of California Berkeley, Berkeley, CA; 3. Department of Physics, University of California 4:06 Berkeley, Berkeley, CA; 4. Advanced Light Source, Lawrence FB-10. Ultrafast optical parametric pumping of magnetization Berkeley National Laboratory, Berkeley, CA reorientation and precessional dynamics in DyFe2/YFe2 1 1 1 exchange springs. L. Shelford , Y. Liu , U. Al-Jarah , P.A. de 2:30 Groot2, G.J. Bowden2, R.C. Ward3 and R.J. Hicken11. School of Physics, University of Exeter, Exeter, Devon, United Kingdom; 2. FC-04. Thermal evolution of nano-scale phase coexistence during School of Physics and Astronomy, University of Southampton, first order magneto-structural transition in FeRh. J. Kim1, Southampton, Hampshire, United Kingdom; 3. Clarendon Y. Choi1, D.J. Keavney1, M.V. Holt1, S. Moyerman2, V. Uhlir2, Laboratory, University of Oxford, Oxford, Oxfordshire, United D. Arena3, E.E. Fullerton2 and P.J. Ryan11. Argonne National Kingdom Laboratory, Argonne, IL; 2. University of California, San Diego, San Diego, CA; 3. Brookhaven National Laboratory, Upton, NY 4:18 2:42 FB-11. Magnetization dynamics for L10-FePd thin films with perpendicular magnetic anisotropy. S. Iihama1, S. Mizukami2, FC-05. Combined surface and transmission Photo-Emission Electron M. Khan1, H. Naganuma1, M. Oogane1 and Y. Ando11. Microscopy for the investigation of 3D micromagnetic Department of Applied physics, Tohoku university, Sendai, states.S. Jamet1, S. Da-Col1, N. Rougemaille1, A. Locatelli2, Miyagi, Japan; 2. WPI-AIMR, Tohoku University, Sendai, Miyagi, T.O. Mentes2, B. Santos Burgos2, L. Cagnon1, O. Fruchart1 and Japan J. Toussaint11. Institut Néel, CNRS, Grenoble, France; 2. ELETTRA Sincrotrone, Trieste, Italy

2:54 THURSDAY PLAZA BALLROOM E FC-06. Magneto-optic three-dimensional display composed of AFTERNOON magnetic garnet films. H. Takagi1, K. Nakamura1, 1 1 1 1:30 K. Matsugami , P. Lim and M. Inoue 1. Toyohashi University of Technology, Toyohashi, Japan Session FC ADVANCED MICROSCOPY AND 3:06 CHARACTERIZATION FC-07. Atom probe tomography direct imaging of thermally activated atomic diffusions through grain boundaries for Peter Fischer, Chair exhange biased stacks.F. Letellier1, L. Lechevallier1, R. Lardé1, J. Le Breton1, A. Kamil2,3, V. Baltz3, S. Auffret3 and B. Dieny31. 1:30 GPM, Rouen, France; 2. CROCUS Technology, Grenoble, France; 3. SPINTEC, Grenoble, France FC-01. Tailoring the chirality of magnetic domain walls by interface engineering. (Invited) G. Chen11. NCEM/MSD, Lawrence Berkeley National Laboratory, Berkeley, CA 3:18 FC-08. Alternating magnetic force microscopy: high-frequency 2:06 magnetic field measurement by excitation of soft magnetic tip.Y. Kinoshita1, G. Egawa2, S. Yoshimura2 and H. Saito21. FC-02. Effect of capping material on interfacial ferromagnetism in Venture Business Laboratory, Akita University, Akita, Akita, 2 1 3 FeRh thin films.C. Baldasseroni , C. Bordel , G.K. Palsson , Japan; 2. Graduate School of Engineering and Resource Science, 3 3 3 3 3 S. Valencia , A.A. Unal , S. Nemsak , A.X. Gray , A.M. Kaiser , Akita University, Akita, Akita, Japan F. Kronast4, J. Herrero-Albillos4, C.M. Schneider4, C.S. Fadley3, J.A. Borchers5, B. Maranville5 and F. Hellman1,31. Physics, University of California at Berkeley, Berkeley, CA; 2. Materials 3:30 Science, University of Berkeley, Berkeley, CA; 3. Materials FC-09. Dissipation in Magnetic Force Microscopy: artifacts or Science Division, Lawrence Berkeley National Laboratory, information? A. Asenjo1, O. Iglesias-Freire1, M. Jaafar2, Berkeley, CA; 4. Helmholtz Zentrum, Berlin, Germany; 5. NCNR, P. Garcia-Mochales2, J.R. Bates3, Y. Miyahara3, P.H. Grütter3 and NIST, Gaithersburg, MD J.J. Saenz21. MIT, ICMM-CSIC, Madrid, Spain; 2. Fisica de la Materia Condensada, UAM, Madrid, Spain; 3. Department of Physics, McGill University, Montreal, QC, Canada 202 PROGRAM PROGRAM 203

3:42 2:18 FC-10. Imaging Dynamic Magnetoelectric Coupling in Multiferroic FD-03. Quantum gates controlled by spin chain soliton excitations. Bilayers. O. Vlasin1, S. Cherifi2, N. Dix1, F. Sanchez1, A. Cuccoli1, D. Nuzzi1, R. Vaia2 and P. Verrucchi21. Dipartimento J. Fontcuberta1 and G. Herranz11. ICMAB-CSIC, Bellaterra, di Fisica e Astronomia, Univ Firenze, Sesto Fiorentino (FI), Italy; Spain; 2. IPCMS, CNRS and UdS 23, Strasbourg, France 2. Istituto dei Sistemi Complessi, CNR- Consiglio nazionale delle Ricerche, Firenze, FI, Italy 3:54 2:30 FC-11. Kerr Microscopy Studies of the Effects of Bending Stress on Galfenol. G. Raghunath1 and A.B. Flatau11. Department of FD-04. Experimental quantum FORC study of hysteretic processes at Aerospace Engineering, University of Maryland, College Park, ultra-low temperature in Fe8 molecular MD nanomagnets.R. Tanasa1, A. Stancu1, G. Yue2, I. Chiorescu2 and W. Wernsdorfer31. Department of Physics, Alexandru Ioan Cuza University of Iasi, Iasi, Romania; 2. Department of Physics and 4:06 National High Magnetic Field Laboratory, Florida State FC-12. Magnetic bistability of Fe nanowires epitaxially grown on University, Tallahassee, FL; 3. Institut Neel, Grenoble, France Ru(0001). A. Quesada1, M. Monti2, A. Serrano1, I. Krug3, 4 4 3 3 3 A.T. N’Diaye , G. Chen , F. Nickel , D. Gottlob , H. Doganay , 2:42 J. de la Figuera2, A.K. Schmid4 and J. Fernández11. Electroceramics, Instituto de Cerámica y Vidrio, Madrid, Madrid, FD-05. Current-Driven Spin Dynamics of Artificially Constructed Spain; 2. Instituto de Química Física Rocasolano, CSIC, Madrid, Quantum Magnets. (Invited) S. Krause11. Institute of Applied Madrid, Spain; 3. Research Center Jülich GmbH, Jülich, Physics, University of Hamburg, Hamburg, Germany Germany; 4. NCEM, Lawrence Berkeley National Laboratory, Berkeley, CA 3:18

4:18 FD-06. Magnetic properties of arrays of zigzag chains of FePt and CoPt on Pt (001) surface.P. Kumar1,3, A.K. Solanki2, FC-13. Induced transverse anisotropy in permalloy nanowires by R. Skomski3 and A. Kashyap1,31. School of Basic Sciences, current pulses application. M. Benitez Romero1, D. McGrouther1 Indian Institute of Technology Mandi, Mandi, Himachal Pradesh, and S. McVitie11. Physics and Astronomy, University of Glasgow, India; 2. Central Computer Center, MNIT, Jaipur, India; 3. Glasgow, United Kingdom Department of Physics and Astronomy and Nebraska Center for Materials and Nanoscience, University of Nebraska, Lincoln, NE

3:30 THURSDAY PLAZA BALLROOM D FD-07. Magnetism in selected Prussian Blue Analogs. M. Shestra1, AFTERNOON S. Adak1,3, J. Peterson1, L. Daemen2, V. Zapf2, K. Page2 and 1,2 1:30 H. Nakotte 1. Physics, New Mexico State University, Las Cruces, NM; 2. Los Alamos National Laboratory, Los Alamos, NM; 3. University of Tennessee, Knoxville, TN Session FD

LOW-DIMENSIONAL AND MOLECULAR 3:42 MAGNETISM FD-08. Photo-controlled magnetism of Prussian blue analogue Tian-Heng Han, Chair heterostructures: a variable temperature powder diffraction study. M. Andrus1, C.H. Li1, K.A. Somodi1, A.C. Felts1, 1:30 M.K. Peprah2, P.A. Quintero2, E.S. Knowles2, K.A. Abboud1, M.W. Meisel2 and D.R. Talham11. Chemistry, University of FD-01. Single Magnetic Atoms on Thin MgO Films. (Invited) Florida, Gainesville, FL; 2. Physics, University of Florida, 1 1 1 1 S. Baumann , I.G. Rau , C.P. Lutz and A.J. Heinrich 1. IBM Gainesville, FL Almaden Research Center, San Jose, CA

3:54 2:06 FD-09. Ligand-driven Electronic Structure of FeII Molecules: A Way FD-02. Studies of Coherent Quantum Dynamics Associated with a to Develop Spin-crossover Complexes. N.A. Tuan1,2 and 1 Mononuclear Holmium Single-Molecule Magnet.S. Ghosh , T.V. Nguyen11. Faculty of Physics, Hanoi University of Science, 2 2 2 1 S. Cardona-Serra , A. Gaita-Ariño , E. Coronado and S. Hill 1. Vietnam National University, Hanoi, Viet Nam; 2. School of Physics and NHMFL, Florida State University, Tallahassee, FL; Materials Science, Japan Advanced Institute of Science and 2. Instituto de Ciencia Molecular, Universidad de Valencia, Technology, Nomi, Ishikawa, Japan Valencia, Spain 204 PROGRAM PROGRAM 205

4:06 2:18 FD-10. Exchange Interactions and Elastic Constants in a Low- FE-05. Atomistic simulation of Heat Assisted Magnetic Recording 1 1 1 Dimensional Magnetic System Cu(H2O)2(en)SO4 by Ab-Initio with ECC media.W.J. Fan , R.F. Evans and R.W. Chantrell 1. Calculations. R. Sykora1, D. Legut1 and U.D. Wdowik21. CNT - Department of Physics, University Of York, York, England, United Nanotechnology Centre, VSB-Technical University of Ostrava, Kingdom Ostrava-Poruba, Czech Republic; 2. Institute of Technology, Pedagogical University, Cracow, Poland 2:30 FE-06. Granular nanostructure and magnetic characteristics of FePt- 4:18 1,2 MOx/FePt-C (M = Ti, Si) stacked granular films. T. Ono , 1,2 2 3 3 FD-11. Characterization of Trippkeite, CuAs2O4; A New Low T. Moriya , M. Hatayama , N. Kikuchi , S. Okamoto , Dimensional, Quantum-Spin-Chain, Ferromagnet. K. Caslin1,2, O. Kitakami3 and T. Shimatsu2,41. Electronic Device Laboratory, R.K. Kremer1, A. Schulz1, A. Muñoz3, F. Pertlik4, J. Liu5, Fuji Electric Co., Ltd., Sendai, Miyagi, Japan; 2. Frontier M.H. Whangbo5 and F.S. Razavi21. Max Planck Institute for Solid Research Institute for Interdisciplinary Sciences(FRIS), Tohoku State Research, Stuttgart, Germany; 2. Brock University, St. University, Sendai, Miyagi, Japan; 3. Institute of Catharines, ON, Canada; 3. Universidad de La Laguna, Tenerife, Multidisciplinary Research for Advanced Materials (IMRAM), Spain; 4. Vienna University of Technology, Institute of Mineralogy Tohoku University, Sendai, Miyagi, Japan; 4. Research Institute of and Crystallography, Wien, Austria; 5. North Carolina State Electrical Communication(RIEC), Tohoku University, Sendai, University, Raleigh, NC Miyagi, Japan

2:42 FE-07. Adjacent Track Heating Effects in a Heat Assisted Magnetic THURSDAY GOVERNOR’S SQ 14 Recording System. (Invited) J. Dykes1, T. Rausch1, K. Heim1, AFTERNOON P. Lu 1, S. Kalarickal1, J. Tramtham1, A. Sam1 and E. Gage11. 1:30 Seagate Technology, Shakopee, MN

Session FE 3:18 ENERGY-ASSISTED RECORDING MEDIA FE-08. Experimental Determination of Lateral Thermal Conductivity James Bain, Chair in FePt/C Granular Thin Film HAMR Media Using a Model Layered System. H.C. Ho1, A. Sharma1, W. Ong2, J. Malen2, J. Bain1 and J. Zhu11. Data Storage Systems Center, Carnegie 1:30 Mellon University, Pittsburgh, PA; 2. Mechanical Engineering, FE-01. Temporal Analysis for the Switching Distribution of FePt Carnegie Mellon University, Pittsburgh, PA Grains during Heat-Assisted Writing. S. Wang1 and 1 R.H. Victora 1. Electrical and Computer Engineering, Center for 3:30 Micromagnetics and Information Technologies, Minneapolis, MN FE-09. Magnetization Switching in L10-FePt Using Spin Waves with Large Oscillation Amplitude. T. Seki1, K. Hotta1 and 1:42 K. Takanashi11. Institute for Materials Research, Tohoku FE-02. A Two-Step Heating Scheme for Heat Assisted Magnetic University, Sendai, Japan Recording. S. Xiong1, J. Kim1, Y. Wang1, X. Zhang1 and 1 D. Body 1. Mechanical Engineering, University of California at 3:42 Berkeley, Berkeley, CA FE-10. Effects of Temperature on Intergranular Exchange Coupling 1 1 in L10 FePt Thin Films. E.Y. Huang and M.H. Kryder 1. 1:54 Electrical and Computer Engineering, Carnegie Mellon FE-03. Performance benefits from pulsed laser heating in heat University, Pittsburgh, PA assisted magnetic recording. B. Xu1, Z. Cen1, J. Goh2, J. Li1, 1 1 1 2 Y. Toh , J. Zhang , K. Ye and C. Quan 1. Data Storage Institute, 3:54 Singapore, Singapore; 2. Department of Mechanical Engineering, National University of Singapore, Singapore, Singapore FE-11. Characteristic Impedances and Reflection Coefficients at the Medium for Highly Confined Plasmonic Modes on Near Field Transducers for HAMR. J.A. Bain11. ECE, Carnegie Mellon 2:06 University, Pittsburgh, PA FE-04. Heat Assisted Magnetic Recording: Grain size dependency, enhanced damping, and a simulation/experiment comparison. P. Huang1 and R.H. Victora11. Electrical and Computer Engineering, University of Minnesota, Minneapolis, MN 206 PROGRAM PROGRAM 207

4:06 2:18

FE-12. SNR impact of grain-to-grain heating variation in heat FF-05. Magnetic structure analysis of (Nd1-xDyx)2Fe14B (x = 0, 0.125). assisted magnetic recording. J. Zhu1 and H. Li11. Data Storage K. Saito1, N. Inami1, T. Ueno2, H. Otori1, Y. Takeichi1, Systems Center, Carnegie Mellon Univ, Pittsburgh, PA R. Sagayama1, R. Kumai1, T. Ishigaki3, M. Yano4, A. Kato4, N. Miyamoto4, T. Shoji4, A. Manabe4, Y. Kaneko5 and K. Ono11. Institute of Materials Structure Science, High Energy Accelerator 4:06 Research Organization, Tsukuba, Ibaraki, Japan; 2. National Institute for Materials Science, Tsukuba, Ibaraki, Japan; 3. FE-13. On switching and switching field distribution of FePt L10 nanostructures. J.W. Lau1, J.A. Yu1, A.M. Castillo1, C. Kim2 and Frontier Research Center for Applied Atomic Sciences, Ibaraki M.H. Kryder21. Materials Science and Engineering Division, University, Tokai, Ibaraki, Japan; 4. Toyota Motor Corporation, NIST, Gaithersburg, MD; 2. Electrical and ComputerEngineering, Toyota, Aichi, Japan; 5. Toyota Central R&D Labs. Inc., Carnegie Mellon University, Pittsburgh, PA Nagakute, Aichi, Japan

2:30 FF-06. Effects of 1 MeV fast neutrons on FeNdB permanent magnets. THURSDAY GOVERNOR’S SQ 15 A. Samin1, J. Qiu1, T. Ciccarello1, L. Cao1 and J. Hattrick- 2 AFTERNOON Simpers 1. Mechanical and Aerospace Engineering, Ohio State University, columbus, OH; 2. Chemical Engineering, University 1:30 of South Carolina, Columbia, SC Session FF BORIDE PERMANENT MAGNETS: 2:42 FUNDAMENTALS AND ADVANCED FF-07. Nano-XMCD characterization of single particle and grain boundaries of nanocrystalline Nd-Fe-B permanent magnets. CHARACTERIZATION II Y. Takeichi1, M. Yano2, A. Kato2, T. Shoji2, A. Manabe2, J. Raabe3 M. Kramer, Chair and K. Ono11. Institute of Materials Structure Science, High Energy Accelerator Research Organization, Tsukuba, Japan; 2. Toyota Motor Corporation, Toyota, Japan; 3. Swiss Light Source, 1:30 Paul Scherrer Institute, Villigen, Switzerland FF-01. Magnetic Structrure of Nd2Fe14B. T. Yoshioka1, H. Tsuchiura1, 1 2 M. Naoko and P. Novák 1. Department of Applied Physics, 2:54 Tohoku University, Sendai, Miyagi, Japan; 2. Institute of Physics, ASCR, Prague, Czech Republic FF-08. Grain boundary phase engineering in NdFeB films. D. Le Roy1, O. Akdogan1, G. Ciuta1, N. Dempsey1 and D. Givord11. Institut Néel, CNRS, Grenoble, France 1:42

FF-02. Imaging of Magnetic Domain Evolution in Nd-Fe-B Sintered 3:06 Magnet Using Scanning Hard-X-ray Microprobe. M. Suzuki1, T. Nakamura1, A. Yasui1, Y. Kotani1, N. Tsuji1, T. Ohkubo2, FF-09. Atomistic modelling of temperature dependent properties of K. Hono2 and S. Hirosawa21. JASRI/SPring-8, Sayo, Hyogo, NdFeB. R.F. Evans1, R. Cuadrado1, M.I. Probert1, G. Hrkac2, Japan; 2. NIMS, Tsukuba, Ibaraki, Japan T. Schrefl3 and R.W. Chantrell11. Department of Physics, University Of York, York, England, United Kingdom; 2. College of Engineering, Mathematics and Physical Sciences, University of 1:54 Exeter, Exeter, England, United Kingdom; 3. St. Polten University FF-03. Influence of microstructure on magnetic domain propagation of Applied Sciences, St Polten, Austria in Nd-Fe-B sintered magnet analyzed by SEM/EBSD and in- 1 1 1 situ Kerr microscope. T. Maki , M. Natsumeda , T. Nishiuchi 3:18 and M. Takezawa21. Hitachi Metals, Shimamoto, Japan; 2. Kyushu Institute of Technology, Kitakyusyu, Japan FF-10. Impact of different Nd-rich crystal-phases on the coercivity of Nd-Fe-B grain ensembles. G. Hrkac1, T.G. Woodcock3, K.T. Butler2, M.T. Bryan1, T. Schrefl5 and O. Gutfleisch41. 2:06 Engineering, Mathematics and Physical Sciences, University of FF-04. Coercivity mechanism researches for bulk Nd-Fe-B Exeter, Exeter, Devon, United Kingdom; 2. Centre for Sustainable permanent magnet by small-angle neutron scattering. Chemical Technologies, University of Bath, Bath, United M. Yano1, K. Ono2, M. Harada3, A. Manabe1, T. Shoji1, A. Kato1 Kingdom; 3. Institute for Metallic Materials, IFW Dresden,, and J. Kohlbrecher41. Advanced Materials Engineering Div., Dresden, Germany; 4. Institute for Materials Science, TU Toyota Motor Corporation, Susono, Japan; 2. High Energy Darmstadt, Darmstadt, Germany; 5. St Poelten Univeristy of Accelerator Research Organization (KEK), Tsukuba, Japan; 3. Applied Sciences, St Poelten, Austria Toyota Central R&D Labs. Inc., Aichi, Japan; 4. Laboratory for Neutron Scattering, Paul Scherrer Institut, Villigen, Switzerland 208 PROGRAM PROGRAM 209

3:30 1:54 FF-11. Microstructure evolution of hot-deformed Nd-Fe-B magnets. FG-03. Manipulation of electromagnetic wave transmission based on J. Liu1,2, H. Sepehri-Amin1, T. Ohkubo1, K. Hioki3, A. Hattori3 anisotropic μ-near-zero metamaterials with magnetic defects. and K. Hono1,21. Elements Strategy Initiative Center for Magnetic K. Zhang1, G. Yang1, J. Fu1, F. Meng1, Q. Wu1 and L. Xiao11. Materials, National Institute for Materials Science, Tsukuba, Dept.of Electronic & Communications Engineering, Harbin Ibaraki, Japan; 2. Graduate School of Pure and Applied Sciences, Institute of Technology, Harbin, Heilongjiang, China University of Tsukuba, Tsukuba, Ibaraki, Japan; 3. Daido Steel Co., LTD, Nagoya, Aichi, Japan 2:06

3:42 FG-04. Highly Adjustable Broadband Metamaterial Absorber Based on Magnetic Medium.Y. Wang1, Y. Cheng1, D. Cheng1, FF-12. Spin-wave dispersion in Nd-Fe-B magnet. K. Ono1, K. Saito1, W. Wang1, Y. Nie1 and R. Gong11. School of Optical and N. Inami1, Y. Takeichi1, M. Yano2, T. Shoji2, A. Manabe2, Electronic Information, Huazhong University of Science and A. Kato2, Y. Kaneko3, D. Kawana4, T. Yokoo1 and S. Itoh11. KEK, Technology, Wuhan, Hubei, China Tsukuba, Japan; 2. Toyota Motor Corporation, Aichi, Japan; 3. Toyota Central R&D Labs. Inc., Aichi, Japan; 4. University of 2:18 Tokyo, Kashiwa, Japan FG-05. Phase Nonreciprocal CRLH Metamaterial Based on Coplanar 1 1 1 1 3:54 Waveguide. A. Porokhnyuk , T. Ueda , T. Ohdo , Y. Kado and T. Itoh21. Electronics, Kyoto Institute of Technology, Kyoto, FF-13. Magnetocrystalline anisotropy of the Fe-sublattice in Japan; 2. Electrical Engineering, University of California, Los R2Fe14B systems.M. Yoshio1, H. Tsuchiura2 and Y. Takuya21. Angeles, CA Research Institute of Electrical Communication, Tohoku University, Sendai, Japan; 2. Department of Applied Physics, 2:30 Tohoku University, Sendai, Japan FG-06. Wideband Ferrite Substrate Integrated Waveguide Isolator Using Shape Anisotropy. S. Beguhn1, X. Yang1 and N.X. Sun11. Northeastern University, Lexington, MA

THURSDAY GOVERNOR’S SQ 16 2:42 AFTERNOON 1:30 FG-07. Phase noise of a hybrid opto-magnetic auto-oscillator. R. Khymyn1,2, V. Tyberkevych1, H. Tang3, O. Prokopenko4 and A. Slavin11. Oakland University, Rochester Hills, MI; 2. Institute Session FG of Magnetism, NASU, Kyiv, Ukraine; 3. Yale University, New METAMATERIALS AND MICROWAVE Haven, CT; 4. Taras Shevchenko National University of Kyiv, DEVICES Kyiv, Ukraine Karen Livesey, Chair 2:54

1:30 FG-08. Millimeter Wave CMOS On-chip Hexagonal Ferrite Circulator. L. Chao1, E. Fu1, V. Koomson1 and M.N. Afsar11. FG-01. Double-negative-index metacomposite based on Fe-based Tufts University, Medford, MA ferromagnetic microwires. Y. Luo1, H. Peng1, F. Qin2, M. Ipatov3, V. Zhukova3, A. Zhukov3 and J. Gonzalez31. Advanced Composite Centre for Innovation and Science, 3:06 Department of Aerospace Engineering, University of Bristol, FG-09. Monolithic Microwave Nonlinear Phase Shifter.B.K. Kuanr1,2, Bristol, United Kingdom; 2. 1D Nanomaterials Group, National A.V. Kuanr3, R.E. Camley1 and Z. Celinski11. Department of Institute for Material Science, Tsukuba, Japan; 3. Dpto. de Fisica Physics, University of Colorado at Colorado Springs, Colorado de Materiales, Fac. Quimicas, Universidad del Pais Vasco, Springs, CO; 2. Electronics Department, Zakir Husain Delhi Bilbao, Spain College (University of Delhi), Delhi, India; 3. Physics Department, Shaheed Rajguru College of Applied Sciences For 1:42 Women (University of Delhi), Delhi, India FG-02. Design for Broadband Polarization Insensitive Metamaterial Absorber.X. Liu1, G. Yang1 and Q. Wu11. School of electronic 3:18 and information engineering, Harbin Institute of Technology, FG-10. Multilayer Magnetic Waveguides: Optimizing Nonreciprocal Harbin, Heilongjiang, China Propagation in the 30-80 GHz range. N.R. Anderson1 and R.E. Camley11. Center for Magnetism and Magnetic Nanostructures, University of Colorado Colorado Springs, Colorado Springs, CO 210 PROGRAM PROGRAM 211

3:30 2:18 FG-11. A High Frequency Magnetically Tunable On-wafer Band-stop FH-03. Induced cell death using magnetic hyperthermia with nickel Filter Based on Barium Hexaferrite Thin Films. I. Harward1, nanowires. M.F. Contreras1, T. Ravasi1 and J. Kosel21. Biological K. Linderman1, D. Chen1,2, R.E. Camley1 and Z.J. Celinski11. Environmental Sciences and Engineering, King Abdullah Physics, Univ. of Colo., Colorado Springs, Colorado Springs, University of Science and Technology, Thuwal, Makkah, Saudi CO; 2. State Key Laboratory of Electronic Thin Films and Arabia; 2. Computer, Electrical and Mathematical Sciences and Integrated Devices, University of Electronic Science and Engineering, King Abdullah University of Science and Technology of China, Chengdu, Sichuan, China Technology, Thuwal, Makkah, Saudi Arabia

3:42 2:30 FG-12. High Frequency Tunable Noise Suppressor using Nano FH-04. Temperature dependent heating in Frozen and Liquid Patterned Permalloy film. B. Rahman1, R. Divan2, ferrofluids with Alternating Magnetic Fields. P. Vaishnava1, D. Rosenman2, Y. Peng1, X. Wang1, H. Zhang3 and G. Wang11. R. Regmi2,3, A. Naik2, J. Thakur2 and G. Lawes21. Physics, Electrical Engineering, University of South Carolina, Columbia, Kettering University, Flint, MI; 2. Physics and Astronomy, Wayne SC; 2. Center for Nanoscale Materials, Argonne National State University, Detroit, MI; 3. Medical Physics, Memorial Sloan Laboratory, Lemont, IL; 3. Intel Corporation, Columbia, SC Kettering Cancer Center,, New York, NY

3:54 2:42 FG-13. High isolation Ni-Zn ferrite 2 GHz circulator. J. Lee1, FH-05. Magnetic Induction Heating of Nano-sized Ferrite Y. Hong1, W. Lee1, J. Park1, N. Luhrs1 and C. Yun21. Electrical Particles.H. Huang1, Y. Wang2, Y. Zhang3 and Y. Zhai21. College and Computer Engineering, The University of Alabama, of Material Science and Engineering, Southeast University, Tuscaloosa, AL; 2. Qualcomm Technologies, Inc., San Diego, CA Nanjing, China; 2. Department of Physics, Southeast University, Nanjing, China; 3. College of chemistry and chemical engineering, Southeast University, Nanjing, China

2:54 THURSDAY GOVERNOR’S SQ 12 AFTERNOON FH-06. Effect of Mg Cations on the Biocompatibility, Magnetic, and AC Heating Properties of Superparamagnetic Mg Mn Fe O 1:30 x 1-x 2 4 Nanoparticles.M. Jeun1, S. Park1, J. Lee1, M.P. Hwang1, G. Jang1 and K. Lee11. Center for Biomaterials, Biomedical Research Session FH Institute, Korea Institute of Science and Technology, Seoul, BIO APPLICATIONS: HYPERTHERMIA AND Republic of Korea IMAGING Stephen Russek, Chair 3:06 FH-07. Superparamagnetic Nanoparticle-based Magnetic Nanofluid 1:30 Hyperthermia: Regulating Heat Shock Protein Induction in Retinal Ganglion Cells for the Treatment of Glaucoma. FH-01. Local Temperature Probing and Remotely Controlled Drug M. Jeun1 and K. Lee11. Center for Biomaterials, Biomedical Release Based on Azo–Functionalized Iron Oxide Research Institute, Korea Institute of Science and Technology, Nanoparticles upon Alternating Magnetic Field Exposure. Seoul, Republic of Korea (Invited) T. Pellegrino1,21. National Nanotechnology Laboratory, CNR–NANO, Lecce, Italy; 2. Istituto Italiano di Tecnologia, Genova, Italy 3:18 FH-08. Intracellular performance of tailored nanoparticle tracers in 2:06 Magnetic Particle Imaging. H. Arami1 and K.M. Krishnan11. University of Washington at Seattle, Seattle, WA FH-02. Effect of the distribution of anisotropy constants for hyperthermia applications. G. Vallejo-Fernandez1 and K. O’Grady11. Department of Physics, The University of York, 3:30 York, United Kingdom FH-09. Magnetic relaxation of specific iron oxide core-shell structure for MRI contrast application. M. Yang1,2, P. Lin1, C. Chang3 and C. Lai11. Department of Materials Science and Engineering, National Tsing Hua University, Hsinchu, Taiwan; 2. Material and Chemical Research Laboratories, Industrial Technology Research Institute, Hsinchu, Taiwan; 3. Institute of Biomedical Sciences, Academia Sinica, Taipei, Taiwan 212 PROGRAM PROGRAM 213

3:42 FP-02. Microwave-assisted Magnetization Switching in Permalloy Antidot. H. Huang1, K. Liao1 and Z. Wei11. Department of Power FH-10. Comparison of self polarization effects in synthetic Mechanical Engineering National Tsing Hua University, Hsinchu, antiferromagnetic and vortex magnetic microparticles and Taiwan their use for triggering cancer cells apoptosis. S. Leulmi1, H. Joisten1,2, T. Dietsch1, C. Iss1, M. Morcrette1, P. Sabon1, M. Carrière3, Y. Hou Broutin4 and B. Dieny11. SPINTEC, UMR- FP-03. Collective standing spin wave resonance in Permalloy strip 8191, CEA-INAC/CNRS/UJF-Grenoble 1/Grenoble-INP, arrays with various dipole coupling. H. Chen1, Y. Urazuka1, Grenoble, France; 2. CEA, LETI, MINATEC Campus, 17 Avenue S. Oyabu1, B. Peng1, H. Otsuki1, T. Tanaka1 and K. Matsuyama11. Martyrs, Grenoble, France; 3. SCIB, UMR-E-3, CEA-INAC/ UJF- Faculty of Information Science and Electrical Engineering, Grenoble 1, Grenoble, France; 4. SPrAM, UMR 5819, CEA- Kyushu University, Fukuoka, Fukuoka, Japan INAC/CNRS/UJF-Grenoble 1, Grenoble, France FP-04. Magnetic Hologram made of 1 μm-size Bi-substituted Iron 3:54 Garnet Patterns. T. Ishibashi1, K. Wada1, K. Ohishi1, G. Lou1, T. Yoshida1, Y. Kishimura2, H. Asada2, A. Emoto3, K. Machida4, FH-11. MRI Contrast Agents Based on Synthetic Antiferromagnets. H. Kikuchi4 and N. Shimidzu41. Nagaoka University of 1 1 1 1 K. Stupic , K. Keenan , C. Little and S. Russek 1. National Technology, Niigata, Japan; 2. Yamaguchi University, Yamaguchi, Institute of Standards and Technology, Boulder, CO Japan; 3. AIST, Ibaraki, Japan; 4. NHK Japan Broadcasting Corp., Tokyo, Japan 4:06

FH-12. Transcranial Magnetic Stimulation of Mouse Brain Using FP-05. Magnetic properties on the surface of an Fe52Al48 alloy 1 High-Resolution Anatomical Models. L.J. Crowther1, induced by nanosecond pulsed laser irradiation. H. Kaiju , 2 3 2,3 1 1 R.L. Hadimani1, A.G. Kanthasamy2 and D.C. Jiles11. Department Y. Yoshida , K. Oosawa , S. Watanabe , K. Kondo , A. Ishibashi 4 of Electrical and Computer Engineering, Iowa State University, and K. Yoshimi 1. Research Institute for Electronic Science, Ames, IA; 2. Department of Biomedical Sciences, Iowa State Hokkaido University, Sapporo, Japan; 2. Center for Advanced University, Ames, IA Research of Energy and Materials, Hokkaido University, Sapporo, Japan; 3. Graduate School of Engineering, Hokkaido University, Sapporo, Japan; 4. Graduate School of Engineering, Tohoku 4:18 University, Sendai, Japan FH-13. Beamformer using Source Suppression Reduces Phase Distortion in MEG Source Space. J.H. Hong1, S.C. Jun1 and FP-06. Application of “Snow Jet” Process in Fabrications of K. Kim21. School of Information and Communications, Gwangju Nanomagnet Logic Devices. P. Li 1, F. Shah1, G. Csaba1, Institute of Science and Technology, Gwangju, Republic of Korea; M.T. Niemier2, X.S. Hu2, J.J. Nahas2, W. Porod1 and 2. Korea Research Institute of Standards and Science, Daejeon, G.H. Bernstein11. Dept. of Electrical Engineering, University of Republic of Korea Notre Dame, Notre Dame, IN; 2. Department of Computer Science and Engineering, University of Notre Dame, Notre Dame, IN

FP-07. Bit pattern formation of spinel ferromagnetic oxides by Kr ion THURSDAY EXHIBIT HALL implantation. E. Kita1, Y. Liu1, Y. Utsumi1, J. Morishita1, AFTERNOON K. Suzuki1, T. Kato2, T. Niizeki1, K. Mibu3 and H. Yanagihara11. 2:30 Institute of Applied Physics, University of Tsukuba, Tsukuba, Ibaraki, Japan; 2. Department of Quantum Engineering, Nagoya Session FP University, Nagoya, Japan; 3. Graduate School of Engineering, MAGNETIC PATTERNED FILMS I Nagoya Institute of Technology, Nagoya, Japan (Poster Session) FP-08. Aspect ratio dependent saturation field in patterned Vivian Ng, Chair amorphous Co-Zr-Ta-B thin films with uniaxial anisotropy. S. Zhao1, H. Wu1, D.S. Gardner2 and H. Yu11. Ira A. Fulton FP-01. Non-reciprocal behavior in Permalloy nano-strips at Schools of Engineering, Arizona State University, Tempe, AZ; 2. microwave frequency. B.K. Kuanr1,2, A.V. Kuanr3, R.E. Camley1 Intel Labs, Intel Corp., Santa Clara, CA and Z. Celinski11. Department of Physics, University of Colorado at Colorado Springs, Colorado Springs, CO; 2. Electronics FP-09. Effect of Grain Cutting in Exchange Biased Nanostructures. Department, Zakir Husain Delhi College (University of Delhi), R. Carpenter1, G. Vallejo-Fernandez1, A. Vick1, A. Hirohata2 and Delhi, India; 3. Physics Department, Shaheed Rajguru College of K. O’Grady11. Department of Physics, The University of York, Applied Sciences For Women (University of Delhi), Delhi, India Heslington, YO10 5DD, United Kingdom; 2. Department of Electronics, The University of York, Heslington, YO10 5DD, United Kingdom 214 PROGRAM PROGRAM 215

FP-10. Synthesis and magnetic properties of aligned polyvinyl THURSDAY EXHIBIT HALL pyrrolidone nanofiber arrays with magnetic nanoparticles by 1 2 1 AFTERNOON electrospinning method. T. Ger , K. Hu , C. Huang and 2:30 Z. Wei11. National Tsing Hua University, Hsinchu, Taiwan; 2. Institute of NanoEngineering and MicroSystems, National Tsing Hua University, Hsinchu, Taiwan Session FQ NOVEL MAGNETOCALORICS FP-11. Tilted vortex and mixed reversal modes in exchange biased (Poster Session) nano-dots and nano-ellipses. D.A. Gilbert1, L. Ye1, K. Liu1, Eric Poirier, Chair A. Verea2, S. Agramunt-Puig2, N. del Valle2, C. Navau2, A. Sánchez2, J.F. Lopez-Barbera3, K.S. Buchanan4, A. Hoffmann5, J. Sort2,6 and J. Nogues3,61. Physics, University of California, FQ-01. Entropic and thermal magnetocaloric effects in second-order- Davis, CA; 2. Departament de Fisica, Universitat Autonoma de transition compounds of the series Gd5Si2Ge2-xSnx 1,2 3 4 5 Barcelona, Barcelona, Bellaterra, Spain; 3. ICN2 – Institut A.M. Carvalho , J.G. Tedesco , M.M. Pires , M.E. Soffner , 5 3 3 Catala de Nanociencia i Nanotecnologia, Campus UAB, A.O. Guimarães , A.M. Mansanares and A.A. Coelho 1. Barcelona, Bellaterra, Spain; 4. Physics, Colorado State UNIFESP, São José dos Campos, SP, Brazil; 2. INMETRO, University, Fort Collins, CO; 5. Materials Science Division, Duque de Caxias, RJ, Brazil; 3. UNICAMP, Campinas, SP, Brazil; Argonne National Laboratory, Argonne, IL; 6. Institució Catalana 4. UFVJM, Diamantina, MG, Brazil; 5. UENF, Campos do de Recerca i Estudis Avançats (ICREA), Barcelona, Spain Goytacazes, RJ, Brazil

FP-12. Co thickness dependence on the magnetic anisotropy of FQ-02. Magnetocaloric effect in AS-CAST Gd1-xYx alloys ≤ ≤ 1 2 [Co/Pt]3 multilayer on Si/SiO2 and nanodot arrays. (0.00 x 0.05).E.S. Lara Pérez , J.I. Betancourt Reyes , 1 3 S. Hwang1, S. Yoon1, J. Kwon1 and B. Cho11. School of Materials J.F. Hernández Paz , J.A. Matutes Aquino and J.T. Elizalde 1 Science and Engineering, Gwangju Institute of Science and Galindo 1. Physics and Matemathics, Universidad Autonoma de Techonology, Gwangju, Republic of Korea Ciudad Juarez, Ciudad Juarez, Chihuahua, Mexico; 2. Instituto de Investigaciones en Materiales-UNAM, Mexico, Distrito Federal, Mexico; 3. Centro de Investigacion en Materiales FP-13. Lifting the degeneracy of vortex-pairs resonance in Avanzados, S.C., Chihuahua, Chihuahua, Mexico perpendicular bias fields.S. Jain1, V. Novosad1, J. Pearson1, F.Y. Fradin1 and S.D. Bader11. Materials Science Division, Argonne Nat Lab, Argonne, IL FQ-03. Soft ferromagnetic Gd65Ni35 microwires with enhanced refrigerant capacity for energy-efficient magnetic refrigeration. Y. Yu 1, H. Wang2, F. Qin3, H.X. Peng3, J.F. Sun2, FP-14. Terahertz Wave Modulator Based on Electrically Tuned S.C. Yu4, H. Srikanth1 and M. Phan11. Department of Physics, 1 1 1 2 Graphene Metamaterials. X. He , J. Wang , J. Jiang , G. Yang , University of South Florida, Tampa, FL; 2. School of Materials 2 2 F. Meng and Q. Wu 1. School of Applied Sciences, Harbin Science and Engineering, Harbin Institute of Technology, Harbin, University of Science and Technology, China, Harbin, China; 2. China; 3. Advanced Composite Center for Innovation and 2Dept. of Electronic & Communications Engineering, Harbin Science, University of Bristol, Bristol, United Kingdom; 4. Institute of Technology, Harbin, China Department of Physics, Chungbuk National University, Cheongju, Republic of Korea FP-15. Effect of Magnetic Field on the Electronic Transport in 1,2 3 4 Bilayer Graphene Nanomesh. Y. Liu , K. Nomura , H. Su , FQ-04. The magnetic properties and magnetocaloric effect of 5 1,2 M. Zhang and Q. Wang 1. School of Electrical & Electronic GdxEr1-xGa (x=0-1) compounds. X. Zheng1, J. Chen2, F. Hu1, Engineering, Nanyang Technological Uni, Singapore, Singapore; J. Sun1 and B. Shen11. Beijing National Laboratory for 2. School of Physical & Mathematical Sciences, Nanyang Condensed Matter Physics and State Key Laboratory for Technological Uni, Singapore, Singapore; 3. Institute for Magnetism, Institute of Physics, Chinese Academy of Sciences, Materials Research, Tohoku University, Sendai, Japan; 4. Beijing, China; 2. Beijing Institute of Aerospace Testing Division of Materials Science, Nanyang Technological Uni, Technology, China Aerospace Science and Technology Singapore, Singapore; 5. Data Storage Institute, (A*STAR) Corporation, Beijing, China Agency for Science, Singapore, Singapore

FQ-05. Magnetic and magnetothermal properties of amorphous (Gd1- FP-16. Temperature Dependent Spin-Alignment in 1,2 2 1,2 xTbx)12Co7 alloys. D. Shishkin , A. Volegov and N. Baranov 1. Antiferromagnetic/Ferromagnetic Bilayer Nanostructures. Institute of Metal Physics, Russian Academy of Science, 1 2 4 1 E. Folven , R.V. Chopdekar , S.T. Retterer , T. Tybell , Yekaterinburg, Russian Federation; 2. Institute of Natural 3 1 Y. Takamura and J.K. Grepstad 1. Department of Electronics and Sciences, Ural Federal University, Yekaterinburg, Russian Telecommunications, NTNU, Trondheim, Norway; 2. Paul Federation Scherrer Institute, Villigen, Switzerland; 3. Department of Chemical Engineering and Materials Science, University of California Davis, Davis, CA; 4. Center for Nanophase Materials Sciences and Biosciences Divisions, Oak Ridge National Laboratory, Oak Ridge, TN 216 PROGRAM PROGRAM 217

≤ ≤ FQ-06. Magnetocaloric effect in GdCoxAl2-x system for 0.15 x 1 FQ-14. Phase Diagram And Magnetocaloric Effects In Ni50Mn35 (In1−x 1 2 1 1 1 2 compositions. H. Fu , R.L. Hadimani , M.H. Wang , B.H. Teng Crx)15 and (Mn1−x Crx) NiGe1.05 Alloys. A. Quetz , T. Samanta , and D.C. Jiles21. Department of Physical Electronics, University I. Dubenko1, S. Stadler2 and N. Ali11. Department of Physics, of Electronic Science and Technology of China, Chengdu, Southern Illinois University Carbondale, Carbondale, IL; 2. Sichuan, China; 2. Department of Electrical and Computer Department of Physics & Astronomy, Louisiana State University, Engineering, Iowa State University, Ames, IA Baton Rouge, LA

FQ-07. Enhancement in the magnetic entropy change on substitution FQ-15. The magnetic and magnetocaloric properties of YFe12-xMnx 1 1 1 1 1 1 1 of Ge in ErSn1.1Ge0.9 S. Gupta , L. Pal and K.G. Suresh 1. compounds. Y. Xia , W. Yang , H. Du and J. Yang 1. Peking Physics, Indian Institute of Technology Bombay, Mumbai India, University, Beijing, China Mumbai, Maharashtra, India

FQ-08. Nearly constant magnetic entropy change and adiabatic temperature change in PrGa compound. X. Zheng1, J. Chen2, F. Hu1, J. Sun1 and B. Shen11. Beijing National Laboratory for THURSDAY EXHIBIT HALL Condensed Matter Physics and State Key Laboratory for AFTERNOON Magnetism, Institute of Physics, Chinese Academy of Sciences, 2:30 Beijing, China; 2. Beijing Institute of Aerospace Testing Technology, China Aerospace Science and Technology Session FR Corporation, Beijing, China SOFT MAGNETIC NANOPARTICLES

FQ-09. Magnetic and magnetocaloric properties in melt-spun (Poster Session) 1,2 1 Manuel Vázquez, Co-Chair Mn1.05Ni0.85-xCoxGe (x = 0-0.85) ribbons. X. Zhao , M. Tong , C. Shih2, X. Ning1, W. Chang2, W. Liu1 and Z. Zhang11. Shenyang Sayan Chandra, Co-Chair National Laboratory for Materials Science, Institute of Metal Research, Chinese academy of Sciences, Shenyang, China; 2. FR-01. Synthesis of spherical and cubic Fe Co microstructures by Department of Physics, National Chung Cheng University, Chia- 55 45 ultrasonic-assisted borohydride reduction and Yi, Taiwan magnetorheology of suspension. M. Arief1 and P.K. Mukhopadhyay11. LCMP, Department of Condensed Matter FQ-10. Magnetocaloric effect and the crossover from first-order to Physics & Material Sciences, S. N. Bose National Centre for

tricritical behavior in La0.7Ca0.3Mn0.91Ni0.09O3 manganite. Basic sciences, Kolkata, West Bengal, India P. Zhang1, T. Phan1, T. Thanh1,2 and S. Yu11. Department of Physics, Chungbuk National University, Cheongju, Chungbuk, FR-02. High-energy ball milling of Fe65Co35 alloys in air.P. Sirvent1, Republic of Korea; 2. Institute of Materials Science, Vietnam A. Quesada1, A. Aragón2, P. Marín2, M. García-Hernández3 and Academy of Science and Technology, Hanoi, Viet Nam J. Fernández11. Electroceramics, Instituto de Cerámica y Vidrio, Madrid, Madrid, Spain; 2. Insituto de Magnetismo Aplicado, FQ-11. Magnetic properties of Ni-Mn-In Heusler-type glass-coated UCM-ADIF-CSIC, Madrid, Madrid, Spain; 3. Insituto de Ciencia microwires. V. Zhukova1, M. Ipatov1, A. Granovsky2, J.J. del Val1 de Materiales de Madrid, CSIC, Madrid, Madrid, Spain and A.P. Zhukov1,31. Phys. Mater., UPV/EHU, San Sebastián, Spain; 2. Faculty of Physics,, Moscow State University, Leninskie FR-03. Versatile one-pot synthesis of Co and FeCo nanoparticles. Gory, Moscow, Russian Federation; 3. IKERBASQUE, Basque A. Hines1, N. Milanovic1 and E.E. Carpenter11. Chemistry, Foundation for Science, Bilbao, Spain Virginia Commonwealth University, Richmond, VA

FQ-12. Influence of annealing condition on magnetocaloric effect of FR-04. Fabrication and characterization of Fe nano-particles by MnFe(P,Si) compounds. X. Yibole1, L. Zhang2 and E. Bruck11. 1. sonochemistry method. W. Liu1,2, X. Hu3, A.M. Gabay1, Fundamental Aspects of Materials and Energy, Technology R.V. Neelam1, G.C. Hadjipanayis1 and M. Yue21. Department of University of Delft, Delft, Netherlands; 2. BASF Netherlands B.V., Physics and Astronomy, University of Delaware, Newark, DE; 2. De Meern, Netherlands College of Materials Scicence and Engineering, Beijing University of Technology, Beijing, China; 3. Department of FQ-13. Structural, thermal, and magnetic properties of MnFePGe Materials Science and Engineering, University of Delaware, compounds prepared by spark plasma sintering Newark, DE method.M. Xu1, M. Yue1, D. Zhang1, M. Wang1, D. Liu1 and J. Zhang11. Beijing University of Technology, Beijing, China 218 PROGRAM PROGRAM 219

FR-05. Magnetic properties and biocompatibility of iron FR-13. Influence of temperature and redistribution of cations on the nanoparticles Coated with drugs synthesized by high energy magnetic properties of the MnxZn1-xFe2O4 thermal-sensitive ball milling. R. Akshatala1, C.J. Arout2, P. Pranav Kumar3, ferrofluid prepared by a sol-gel auto-combustion M. Doble3 and M.S. Buddhiraju11. Metallurgical and materials method.W. Wang2, L. Zhuang1, Y. Zhang2, J. Dong2 and Engineering, IIT Madras, Chennai, Tamilnadu, India; 2. Defence H. Shen11. School of Physics and Engineering, State Key metallurgical research laboratory,, Hyderabad, Andhrapradesh, Labratory of Optoelectronic Materials and Technologies, Sun Yat- India; 3. Department of Biotechnology, IIT Madras, Chennai, Sen University, Guangzhou, China; 2. Institute of Optoelectronic Tamilnadu, India Materials and Technology, South China Normal University, Guangzhou, China FR-06. Milling effects on magnetic properties of melt spun Fe-Nb-B alloy.J.J. Ipus1, J.S. Blazquez1, V. Franco1 and A. Conde11. FR-14. Magnetic properties of core-shell manganese-oxide Universidad de Sevilla, Seville, Spain nanoparticles fabricated by inert gas condensation technique. M.A. Khan1, M. Bah1 and I. Shah11. Materials Science and Engineering, University of Delaware, Newark, DE FR-07. Magnetic properties of iron-based soft magnetic composites with SiO2 coating obtained by reverse microemulsion method. S. Wu1, A. Sun1, C. Zou1, J. Dong1 and J. Yang11. School of FR-15. Preparation and characterization of Fe3O4 particles with Material Science and Engineering, University of Science and novel nanosheets morphology and magnetochromatic Technology Beijing, Beijing, China property by a modified solvothermal method. L. Zhuang1, W. Zhang2, Y. Zhao1,3, H. Shen1, H. Lin4 and J. Liang1,31. School of Physics and Engineering, State Key Labratory of FR-08. The influence of frequency on the effective magnetic Optoelectronic Materials and Technologies, Sun Yat-Sen anisotropy of Co nanoparticles.J.F. Calleja1, R. Matarranz1, University, Guangzhou, China; 2. School of Physics and B. Presa1, J. Corrales2 and C. Contreras11. Applied Physics, Optoelectronic Engineering, Guangdong University of University of Oviedo, Oviedo, Asturias, Spain; 2. Computing Technology, Guangzhou, China; 3. School of Chemistry and Engineering, University of Oviedo, Gijon, Asturias, Spain Chemical Engineering, Sun Yat-Sen University, Guangzhou, China; 4. Guanghua School of Stomatology, Hospital of FR-09. Supercritical continuous flow synthesis of nanocrystalline Stomatology, Sun Yat-Sen University, Guangzhou, China cobalt particles. S.E. Smith1 and E.E. Carpenter11. Chemistry, Virginia Commonwealth University, Richmond, VA FR-16. Modeling of magnetostriction of magnetic sponge. P.D. Andriushchenko1, L.L. Afremov1 and M.A. Chernova11. FR-10. Effect of ball milling and dynamic compaction on magnetic School of Natural Sciences, Far Eastern Federal University, 1,2 properties of Al2O3/Co(P) composite particles. E.A. Denisova , Vladivostok, Russian Federation L.A. Kuzovnikova2, R.S. Iskhakov1, A.A. Kuzovnikov3 and E.V. Eremin11. Kirensky Institute of Physics SB RAS, Krasnoyarsk, Russian Federation; 2. Krasnoyarsk Institute of Railways Transport, Krasnoyarsk, Russian Federation; 3. JSC «Pulse technologies», Krasnoyarsk, Russian Federation THURSDAY EXHIBIT HALL AFTERNOON FR-11. Electromagnetic and Microwave Absorbing Properties of Raw 2:30 and Milled FeSiCr Particles. R. Yang1, W. Liang2, C. Chen3 and S. Choi21. Aerospace and Systems Engineering, Feng Chia Session FS University, Taichung, Taiwan; 2. Department of Aeronautics and Astronautics, National Cheng Kung University, Tainan, Taiwan; MULTIFERROICS II: MATERIALS AND 3. Ph.D. program of Mechanical and Aeronautical Engineering, PHENOMENA Feng Chia University, Taichung, Taiwan (Poster Session) Pavel Lukashev, Co-Chair FR-12. Magnetic anisotropy of nanocrystalline FeNi(P) electroless John Burton, Co-Chair deposited in polycarbonate membranes. S.V. Komogortsev1, L.A. Chekanova1, E.A. Denisova1, R.S. Iskhakov1, 2 2 3 S.V. Mel’nikova , N.A. Chizhik and A.A. Bukaemskiy 1. FS-01. Influence of multiferroic BiFeO3 underlayers on the magnetic Kirensky Institute of Physics SB RAS, Krasnoyarsk, Russian configuration of La0.7Sr0.3MnO3 thin films imaged with x-ray Federation; 2. Siberian Federal University, Krasnoyarsk, Russian photoemission electron microscopy. S. Finizio1, C. Mix1, Federation; 3. Institut fur Sicherheitsforschung und M. Buzzi2, F. Kronast3, F. Nolting2, G. Jakob1 and M. Kläui11. Reaktortechnik, Juelich, Germany Institut für Physik, Johannes Gutenberg Universität, Mainz, Germany; 2. Swiss Light Source, Paul Scherrer Institut, Villigen, Switzerland; 3. Helmholtz Zentrum Berlin für Materialien und Energie GmbH, Villigen, Germany 220 PROGRAM PROGRAM 221

1 FS-02. Formation of perovskite BiFeO3(001) films on refined Pt(111) FS-11. Orthorhombic multiferroic thin YbMnO3 films.N.V. Andreev , electrode layer with reduced thickness on glass substrates. V.I. Chichkov1, T.A. Sviridova1, C. Van Haesendonck2, 1 1 1 1 2 H.W. Chang , S.H. Tien , K.T. Tu , C.R. Wang and S.U. Jen 1. A.P. Volodin2 and Y.M. Mukovskiy11. Theorerical Physics & Department of Applied Physics, Tunghai University, Taichung, Quantum Technology, NITU “MISiS”, Moscow, Russian Taiwan; 2. Institute of Physics, Academia Sinica, Taipei, Taiwan Federation; 2. Lab. Solid State Phys. & Magnetism, KU Leuven, Leuven, Belgium FS-03. Theory of spin-electromagnetic waves in multilayered 1 1 1 multiferroics. A.A. Nikitin , V.V. Vitko , A.A. Nikitin , FS-12. Electronic Structure Study of Multiferroic RFe O (R=Er, 1 1 1 2 4 A.B. Ustinov , A.A. Semenov and B.A. Kalinikos 1. Saint Tm, Lu) by Soft X-ray Synchrotron Radiation Spectroscopy. Petersburg Electrotechnical University “LETI”, St. Petersburg, J. Kang1, D.H. Kim1, J. Hwang1, E. Lee1, J. Kim2, B.W. Lee2, Russian Federation C. Kang3 and B.I. Min31. Physics, The Catholic University of Korea, Bucheon, Republic of Korea; 2. Physics, Hankuk FS-04. Second order phonon anomalies near the magnetic phase University of Foreign studies, Yongin, Republic of Korea; 3. transitions in BiFeO3 thin films. M.K. Singh1, G. Singh1 and Physics, POSTECH, Pohang, Republic of Korea R.S. Katiyar21. Material Science, University of Allahabad, Allahabad, India; 2. Department of Physics and Institute of FS-13. Local distortions in multiferroic AgCrO2. A.l. Lopes1, Functional Nano Materials, University of Puerto Rico, San Juan, G.P. Oliveira2,1, T.M. Mendonca2, J. Agostinho Moreira2, Puerto Rico A. Almeida2, J.P. Araujo2, V.S. Amaral3 and J.G. Correia41. Centro de Fisica Nuclear Universidade de Lisboa, Lisboa, Portugal; 2. FS-05. Orientation dependence of exchange bias in epitaxial nstituto de Nanociencia e Nanotecnologia, Universidade do FePt/BiFeO3 bilayer thin films.S. Chiu1, S. Hsiao1 and Porto, Porto, Portugal; 3. Departamento de Fiisica e CICECO, H. Lee11. National Synchrotron Radiation Research Center, Universidade de Aveiro, Aveiro, Portugal; 4. Instituto Tecnologico Hsinchu, Taiwan e Nuclear, Sacavem, Portugal

FS-14. Exchange integrals in SrCo2Ti2Fe8O19. M. Feng1, B. Shao2,3, FS-06. Rectifying property and magnetic related transport behavior 2 2 in TbMnO3/Nb-doped SrTiO3 heterostructure.P. Li 1, W. Li1, Y. Lu and X. Zuo 1. School of Physics, Nankai University, G. Wang1, Y. An1, D. Guo1, J. Xiao1 and W. Tang 11. School of Tianjin, Tianjin, China; 2. College of Information Technical Science, State Key Laboratory of Information Photonics & Science, Nankai University, Tianjin, Tianjin, China; 3. Optical Communication, Beijing University of Posts and Department of Physics, Tsinghua University, Beijing, Beijing, Telecommunications,, Beijing,100876, China China

FS-07. Magnetoelectric Phase dominated by Tb magnetic ordering in FS-15. Low-temperature fabrication of BiFeO3 based multiferroic Multiferroic TbMnO3. W. Tang 1, P. Li2, Q. Huang1 and Z. Wu11. thin films with (111) orientation and formation of composite School of Science, State Key Laboratory of Information Photonics ferromagnetic and ferroelectric domain structure by local electric field. S. Yoshimura1, Y. Sugawara1, J. Lu1, G. Egawa1, and Optical Communications, Beijing University of Posts and 2 1 Telecommunications, Beijing, China; 2. Center for Neutron Y. Kinoshita and H. Saito 1. Graduate School of Engineering & Research, National Insitute of Standards and Technology, Resource Science, Akita University, Akita, Akita, Japan; 2. Gaithesburg, MD Venture Business Laboratory, Akita University, Akita, Akita, Japan

1 FS-08. Multiferroicity in orthorhombic HoMnO3 thin films. T. Han , Y. Liu1 and J.G. Lin21. Department of Applied Physics, National University of Kaohsiung, Kaohsiung, Taiwan; 2. Center for THURSDAY EXHIBIT HALL Condensed Matter Sciences, National Taiwan University, Taipei, AFTERNOON Taiwan 2:30

FS-09. Synthesis of multiferroic Er-Fe-O thin films by ALD/CVD. Session FT R. Mantovan1, S. Vangelista1, C. Wiemer1, A. Lamperti1, G. Tallarida1, E. Chikoidze2, Y. Dumont2 and M. Fanciulli1,31. HEADS, HEAD-MEDIA INTERFACE, AND Laboratorio MDM IMM-CNR, Agrate Brianza (MB), Italy; 2. TRIBOLOGY GEMaC, Université de Versailles St. Quentin en Yvelines-CNRS, Versailles, France; 3. Dipartimento di Scienza dei Materiali, (Poster Session) Università di Milano Bicocca, Milano, Italy Oleksandr Mosendz, Chair

FS-10. Studies of structural and magnetic properties of Mn3ZnC thin FT-01. Nanoscale Readout of Magnetization Direction using films.Y. An 1, Z. Wu1, P. Li1, Y. Li1, D. Guo1, G. Wang1 and Ferromagnetic Resonance Coupled with a Spin-Torque 1 1 1 1 W. Tang 11. School of Science, Beijing University of Posts and Oscillator. H. Suto , T. Nagasawa , K. Kudo , K. Mizushima and 1 Telecommunications, Beijing, China R. Sato 1. Corporate Research & Development Center, Toshiba Corporation, Kawasaki, Japan 222 PROGRAM PROGRAM 223

FT-02. Dual free-layer spin-torque oscillator composed of CoFeB and FT-14. Quantitative relationships between scratch-induced stress and synthetic ferrimagnet layers for read head application in corresponding magnetic strength decay in Perpendicular magnetic recording. T. Nagasawa1, K. Kudo1, H. Suto1, Recording Media. Y. Liu1,2, S. Xiong2, D. Bogy2, J. Lou1 and M. Yamagishi1, K. Mizushima1 and R. Sato11. Corporate G. Zhang11. School of Mechatronics Engineering, Harbin Research & Development Center, Toshiba Corporation, Institute of Technology, Harbin, Heilongjiang, China; 2. Kawasaki, Japan Mechanical Department, University of California, Berkeley, Berkeley, CA FT-03. A Spin Stand Study on Erase Band and Write Width for Shingled Magnetic Recording. S. Chandrasekaran1,2, FT-15. Effect of Humidity on Lubricant Thermal Stability: An P. Supnithi3, C. Warisarn2 and D. Bai41. Western Digital Atomistic Molecular Dynamics Study. M.S. Jhon1,2, (Thailand) Company Ltd.,, Ayutthaya, Ayutthaya, Thailand; 2. R.L. Smith1, P. Chung1, S.H. Vemuri1 and L.T. Biegler11. College of Data Storage Innovation, King Mongkut’s Institute of Chemical Engineering, Carnegie Mellon Univ, Pittsburgh, PA; 2. Technology Ladkrabang, Ladkrabang, Thailand; 3. Faculty of School of Advanced Materials Science and Engineering, Engineering, King Mongkut’s Institute of Technology Ladkrabang, Sungkyunkwan University, Suwon, Republic of Korea Ladkrabang, Thailand; 4. Western Digital, Fremont, CA FT-16. Buff/wipe effects on the Perfluoropolyether Nanoscale Thin FT-05. Etch Damage in Magnetic Thin Film Head Materials. Films. H. Chen1, P. Chung2 and M.S. Jhon2,31. Hewlett Packard L.J. Krayer1,2, B.J. Kirby3, A. Natarajarathinam4 and M. Kief41. Company, San Diego, Armed Forces Pacific; 2. Chemical ECE, University of Maryland, College Park, MD; 2. NIST, Engineering, Carnegie Mellon Univ, Pittsburgh, PA; 3. School of Gaithersburg, MD; 3. Center for Neutron Research, NIST, Advanced Materials Science and Engineering, Sungkyunkwan Gaithersburg, MD; 4. Seagate Technologies, Bloomington, MN University, Suwon, Republic of Korea

FT-06. Time resolved scanning Kerr microscopy study of a synthetic FT-17. Thermal Modeling of Head Disk Interface system in Heat antiferromagnet writer yoke excited by a bi-polar pulse. Assisted Magnetic Recording.M.S. Jhon1,2, s. Vemuri1, W. Yu 1, P.S. Keatley1, R.J. Hicken1, M.A. Gubbins2, P.J. Czoschke3 R. Smith1, P. Chung1 and L.T. Biegler11. Chemical Engineering, and R. Lopusnik31. School of Physics and Astronomy, University Carnegie Mellon Univ, Pittsburgh, PA; 2. School of Advanced of Exeter, Exeter, United Kingdom; 2. Research and Development, Material Science and Engineering, Sungkyunkwan University, Seagate Technology, Londonderry, United Kingdom; 3. Recording Suwon, Gyeonggi-do, Republic of Korea Heads Operation, Seagate Technology, Bloomington, MN FT-18. Film Conformation and Dynamic Properties of Molecularly FT-07. Phenomenological model of Magnetic Flux propagation. Architectured Perfluoropolyethers on the Carbon Surface. K. Rivkin1, M. Benakli1, N. Tabat2 and H. Yin11. Seagate P. Chung1, R. Smith1, S. Vemuri1, S. Park1, L.T. Biegler1 and Technology, Edina, MN; 2. Semaphore, Minneapolis, MN M.S. Jhon1,21. Chemical Engineering, Carnegie Mellon Univ, Pittsburgh, PA; 2. School of Advanced Materials Science and Engineering, Sungkyunkwan University, Suwon, Republic of FT-08. Device Level AFM Pinning Strength and SAF Coupling Korea Strength Measurement through the Thermal Excited SAF FMR Frequency in Read Head. H. Zhao1, A.A. Stankiewicz1, Y. Zhang1 and S. Stokes11. Seagate Technology, Bloomington, MN FT-19. Rheological Analysis on Binary Blends of Perfluoropolyether Lubricants. S. Park1, P. Chung1, L.T. Biegler1 and M.S. Jhon1,21. Chemical Engineering, Carnegie Mellon Univ, Pittsburgh, PA; 2. FT-09. Methods for Characterizing Magnetic Footprints of PMR School of Advanced Materials Science and Engineering, Writer heads. S. Li1, E. Lin1, Z. George1, D. Terrill1, H. Mendez1, Sungkyunkwan University, Suwon, Republic of Korea J. Santucci1 and D. Yu11. Advanced Research, Western Digital Inc, San Jose, CA

FT-10. Influence of Spin-torque on Thermal Mag-noise in a Tunneling Magnetoresistive Read Head with a Low Resistance Area Product below 1.0 Ω.μm2 Y. Endo1, P. Fan1, A. Hotta1 and M. Yamaguchi1,21. Department of Electrical Engineering, Graduate School of Engineering, Tohoku University, Sendai, Miyagi, Japan; 2. NICHe, Tohoku University, Sendai, Miyagi, Japan

FT-12. Simulation of Cross-Talk between Thermal Track Positioning Control and Thermal Flying Height Control. H. Li1 and S. Shen21. Wuhan University, Wuhan City, China; 2. National University of Singapore, Singapore, Singapore 224 PROGRAM PROGRAM 225

THURSDAY EXHIBIT HALL FU-08. Current Induced Perpendicular-Magnetic-Anisotropy Racetrack Memory with Magnetic Field AFTERNOON 1,2 1,2 2,1 1,2 2:30 Assistance.Y. Zhang , W. Zhao , J. Klein , C. Chappert and D. Ravelosona1,21. IEF, Univ. Paris Sud, Orsay, France; 2. UMR 8622, CNRS, Orsay, France Session FU

TAILORING DOMAIN WALLS FU-09. Control of direction of current-induced domain-wall motion (Poster Session) in Pd/Co/Pd by inserting a thin Pt layer at Pd/Co interface. Sylvia Florez, Chair S. Yoo1,2, D. Kim1, B. Min2, K. Shin2 and S. Choe11. Physics, Seoul National University, Seoul, Republic of Korea; 2. Center for Spintonics Research, Korea Institute of Science and Technology, 1 FU-01. Vortex Domain Wall Logic-Gates.K.A. Omari and Seoul, Republic of Korea T.J. Hayward11. Materials Science and Engineering, University of Sheffield, Sheffield, United Kingdom FU-10. Recent development in controlling domain wall motion in Ta- CoFeB-MgO ultra-thin films with perpendicular FU-02. Spin wave based parallel logic operations for stored binary anisotropy.C. Burrowes1, I. Barisic1, N. Lei1, W. Lin1, K. Garcia1, 1 1 data coded with domain walls.Y. Urazuka , H. Chen , L. Herrera Diez1, S. Eimer1, J. Adam1, J. Kim1, N. Vernier1, 1 1 1 1 1 S. Oyabu , B. Peng , H. Otsuki , T. Tanaka and K. Matsuyama 1. T. Devolder1, G. Agnus1, P. Lecoeur1, W. Zhao1, J. Morgan4, Faculty of Information Science and Electrical Engineering, R. Cowburn3, M. Klaui4, B. Ockert5, A. Lamperti6, R. Mantovan6 Kyushu University, Fukuoka, Fukuoka, Japan and D. Ravelosona1,21. University of Paris Sud, Orsay, France; 2. SILTENE technologies, Orsay, France; 3. University of FU-03. Experimental and simulational results of domain wall Cambridge, Cambridge, United Kingdom; 4. University of Mainz, magnetoresistance in a constricted domain wall.Y. Wang1 and Mainz, Germany; 5. Singulus, Kahl, Germany; 6. CNR-IMM C. de Groot11. Nano Research Group, University of Southampton, MDM laboratory, Agrate, Italy Southampton, United Kingdom FU-11. Detection of field and current effects on 360 degree domain FU-04. Domain wall pinning in permalloy nanowires with nano- walls by anisotropic magnetoresistance measurements. 1 1 2,3 1 trench pinning sites. K. Narayanapillai1 and H. Yang11. J. Zhang , L. Tryputen , J.A. Currivan , D.C. Bono and 1 Department of Electrical and Computer Engineering, National C.A. Ross 1. Materials Science and Engineering, MIT, University of Singapore, Singapore, Singapore Cambridge, MA; 2. Physics, Harvard, Cambridge, MA; 3. EECS, MIT, Cambridge, MA

FU-05. Domain wall state space in permalloy nanostructures.H. Corte- Leon1, J. Fletcher1, P. Krzysteczko2, H.W. Schumacher2, FU-12. Characteristics of domain wall motion driven by spin-orbit 1 1 V. Nabaei3, A. Manzin3 and O. Kazakova11. NPL, Teddington, torque in Co/Ni multilayer wires. D. Bromberg , V. Sokalski , 1 1 Middlesex, United Kingdom; 2. PTB, Braunschweig, Germany; 3. M.T. Moneck and J. Zhu 1. Electrical and Computer INRIM, Turin, Italy Engineering, Carnegie Mellon University, Pittsburgh, PA

FU-06. Behavior of Accordion-like Domain Motion in [Co/Pd] FU-13. Rashba spin torque fields on the surface of graphene coupled 1 2,1 Nanowires by Introducing One Weak Trap-site. M. Okuda1, to magnetic layers with domain wall textures.J. Chen , S. Tan 1 Y. Miyamoto1, E. Miyashita1 and N. Hayashi11. NHK Science & and M.B. Jalil 1. Information Storage Materials Laboratory, Technology Research Laboratories, Tokyo, Japan Electrical and Computer Engineering Department, National Univ Singapore, Singapore, Singapore; 2. Data Storage Institute, Singapore, Singapore FU-07. Two-barrier stability in current-induced domain-wall motion device. K. Kim1, R. Hiramatsu1, T. Koyama1, K. Ueda1, Y. Yoshimura1, D. Chiba1,2, K. Kobayashi1, Y. Nakatani3, FU-14. Fast domain wall motion in a MTJ under vertical current 1,2 1 1 S. Fukami4, M. Yamanouchi4,5, H. Ohno4,6, H. Kohno7, injection. P. Metaxas , J. Sampaio , A. Chanthbouala , 1,3 1 1 4,5 G. Tatara8,9 and T. Ono11. Kyoto University, Kyoto, Japan; 2. R. Matsumoto , A. Anane , A. Fert , K.A. Zvezdin , 3 3 3 3 Japan Science and Technology Agency, Saitama, Japan; 3. K. Yakushiji , H. Kubota , A. Fukushima , S. Yuasa , 6 6 6 6 University of Electro-communications, Tokyo, Japan; 4. Center K. Nishimura , Y. Nagamine , H. Maehara , K. Tsunekawa , 1 1 for Spintronics Integrated Systems, Tohoku University, Sendai, V. Cros and J. Grollier 1. Unite Mixte de Physique CNRS/Thales Japan; 5. Laboratory for Nanoelectronics and Spintronics, & Universite Paris-Sud 11, Palaiseau, France; 2. School of Tohoku University, Sendai, Japan; 6. WPI Advanced Institute for Physics, University of Western Australia, Crawley, WA, Australia; Materials Research, Tohoku University, Sendai, Japan; 7. Osaka 3. National Institute of Advanced Industrial Science and University, Osaka, Japan; 8. Department of Physics Tokyo Technology (AIST), Tsukuba, Japan; 4. A. M. Prokhorov General Metropolitan University, Tokyo, Japan; 9. RIKEN Center for Physics Institute of RAS and Moscow Institute of Physics and Emergent Matter Science, Saitama, Japan Technology, Moscow Region, Russian Federation; 5. Istituto P.M. s.r.l., Torino, Italy; 6. Process Development Center, Canon ANELVA Corporation, Kanagawa, Japan 226 PROGRAM PROGRAM 227

FU-15. Distinct Universality Classes of Domain Wall Roughness in FV-04. Spin and orbital moments of Co-carbide nanoparticles for Two-Dimensional Pt/Co/Pt Films. K. Moon1,2, D. Kim2, permanent magnet applications. G.E. Sterbinsky1, K.J. Carroll2, S. Yoo2,3, C. Cho2, S. Hwang2, B. Kahng2, B. Min3, K. Shin3 and H. Yoon2, Y. Meng2, Z.J. Huba3, E.E. Carpenter3 and S. Choe21. Center of Nano measurements, Korea Research D.A. Arena11. Photon Sciences, Brookhaven National Laboratory, Institute of Standards and Science, Daejeon, Republic of Korea; Upton, NY; 2. Department of Nanoengineering, University of 2. CSO and Department of Physics, Seoul National University, California, San Diego, La Jolla, CA; 3. Department of Chemistry, Seoul, Republic of Korea; 3. Center for Spintronics Research, Virginia Commonwealth University, Richmond, VA Korea Institute of Science and Technology, Seoul, Republic of Korea FV-05. Batch optimization and scale up of nanostructured cobalt carbide permanent magnet powders processed using different FU-16. Control of Magnetic Domain Wall Mobility in Pt/Co/Pt polyols. M. Zamanpour1, V.G. Harris2, Y. Chen2, L.H. Lewis1 and systems. D. Kim1, S. Yoo1,2, K. Moon1,3, B. Min2 and S. Choe11. P. Taheri11. Chemical Engineering, Northeastern University, Center for Subwavelength Optics and Department of Physics, Boston, MA; 2. Northeastern University, Boston, MA Seoul National University, Seoul, Republic of Korea; 2. Center for Spintronics Research, Korea Institute of Science and Technology, FV-06. Thermal stability of Fe16N2 on non-magnetic Ag under layer. Seoul, Republic of Korea; 3. Korea Research Institute of X. Zhang1,2, M. Yang1, L.F. Allard3 and J. Wang1,21. The Center Standards and Science, Seoul, Republic of Korea for Micromagnetics and Information Technologies (MINT) & Electrical and Computer Engineering Department, University of Minnesota, Minneapolis, MN; 2. School of Physics and Astronomy, University of Minnesota, Minneapolis, MN; 3. High Temperature Materials Laboratory, Materials Science and THURSDAY EXHIBIT HALL Technology Division, Oak Ridge National Laboratory, Oak Ridge, AFTERNOON TN 2:30 FV-07. FeN Foils by Nitrogen Ion-Implantation. Y. Jiang1, A. Mehedi1, Session FV Y. Wang2 and J. Wang11. Department of Electrical and Computer INTERMETALLICS AND OTHER HARD Engineering, University of Minnesota, Minneapolis, MN; 2. Ion Beam Materials Laboratory, Los Alamos National Laboratory, MAGNETIC MATERIALS III Los Alamos, NM (Poster Session) Gino Hrkac, Co-Chair FV-08. Electrochemical Preparation and Characterization of Room Frederic Mazaleyrat, Co-Chair Temperature L10 Ordered Co1-xPtx Thin Films and Nanowires. S. Riaz1 and S. Naseem11. Centre of Excellence in FV-01. Effects of carbon nanoparticles on magnetic properties of Solid State Physics, University of the Punjab, Lahore, Pakistan mechanically alloyed MnAl permanent magnets. P. Taheri1,2, Y. Chen1,2, O. Obi1,2, M. Zamanpour1 and V.G. Harris1,21. Center FV-09. Cost effective fabrication of oriented magnetic thin films with for Microwave Magnetic Materials and Integrated Circuits, enhanced energy product by nanoimprint lithography. Northeastern University, Boston, MA; 2. Electrical and Computer R. Thantirige1, J. John2, K.R. Carter2 and M. Tuominen11. Engineering, Northeastern University, Boston, MA Physics, University of Massachusetts, Amherst, MA; 2. Polymer Science and Engineering, University of Massachusetts, Amherst, FV-02. MnAlC/FeCo Exchange-Coupled Permanent Magnets. MA O. Obi1, M. Lucas2, M. Wang2, Y. Chen1, J.E. Shield2 and V.G. Harris11. Center for Microwave Magnetic Materials and FV-10. 9 T High Magnetic Field Annealing Effects on FeN Bulk Integrated Circuits, Electrical and Computer Engineering, Sample. Y. Jiang1, V. Dabade2, M.P. Brady3, O. Rios3, Northeastern University, Boston, MA; 2. Department of R.D. James2 and J. Wang11. Department of Electrical and Mechanical and Materials Engineering, University of Nebraska, Computer Engineering, University of Minnesota, Minneapolis, Lincoln, NE MN; 2. Department of Aerospace Engineering and Mechanics, University of Minnesota, Minneapolis, MN; 3. Materials Science FV-03. Exchange coupled cobalt carbide nanocomposite as rare earth & Technology Division, Oak Ridge National Laboratory, Oak free permanent magnets; Nucleation and growth study by Ridge, TN time resolved in situ QXAFS. H. Yoon1, A. Xu1, K.J. Carroll1 and S. Meng11. NanoEngineering, UC San Diego, La Jolla, CA FV-11. Magnetic and structural properties of MnBi multilayered thin films. T. Hozumi1,2, P. LeClair1, G. Mankey1, C. Mewes1, H. Sepehri-Amin3, K. Hono3 and T. Suzuki11. Center for Materials for Information Technology, The University of Alabama, Tuscaloosa, AL; 2. Advanced Technology Development Center, TDK Corporation, Narita, Japan; 3. National Institute for Materials Science, Tsukuba, Japan 228 PROGRAM PROGRAM 229

FV-12. Magnetization, Exchange and Anisotropy Trends in Alloys FW-06. Study of dislocations in two-dimensional ferrofluid droplet with Heavy Transition Metals.P. Kumar1,2, M. Koten3, lattices. C. Lee1, H. Tsai1 and Z. Wei11. Department of Power W.Y. Zhang2, B. Balamurugan2, P. Manchanda1,2, A. Kashyap1,2, Mechanical Engineering, National Tsing Hua University, J.E. Shield2, D.J. Sellmyer2 and R. Skomski21. School of Basic Hsinchu, Taiwan Sciences, Indian Institute of Technology Mandi, Mandi, Himachal Pradesh, India; 2. Department of Physics and Astronomy & FW-07. Dual Rotations of Arrayed Ferrofluid Drops in a Rotating NCMN, University of Nebraska, Lincoln, NE; 3. Department of Magnetic Field.C. Chen1, H. Lin1 and H. Hsueh11. Mechanical Mechanical and Materials Engineering & NCMN, University of Engineering, National Chiao Tung University, Taiwan, ROC, Nebraska, Lincoln, NE Hsinchu, Taiwan

FV-13. To solve the energy product paradox in hard/soft multilayers: FW-08. Stable Vortex Magnetite Nanorings Colloid: Micromagnetic perpendicular or parallel anisotropy? G. Zhao1 and Simulation and Experimental Demonstration. Y. Yang 1, X. Zhang11. College of Physics and Electronic Engineering, X. Liu2, J. Yi4, Y. Yang1, H. Fan3 and J. Ding11. Department of Sichuan Normal University, Chengdu, Sichuan, China Materials Science and Engineering, National University of Singapore,, Singapore, Singapore; 2. School of Chemical Engineering, Northwest University, Xi’an, China; 3. School of Physics, National University of Ireland Galway, Galway, Ireland; 4. School of Materials Science and Engineering, University of THURSDAY PLAZA BALLROOM A New South Wales, Kensington, NSW, Australia AFTERNOON 2:30 FW-09. Investigation of the Magnetic Properties in Fe3O4-gold Ferrofluid Functionalized by Mauritia flexuosa L. Oil. Session FW J.H. Dias Filho1,2, J.L. López2,3, R.M. Paniago3,2, H. Pfannes3,2 MAGNETIC FLUIDS and K. Balzuweit3,21. Departamento de Ciências Exatas, Universidade Estadual de Montes Claros, Montes Claros, Minas (Poster Session) Gerais, Brazil; 2. Centro de Ciências Biológicas e da Natureza, Norman Wereley, Chair Universidade Federal do Acre, Rio Branco, Acre, Brazil; 3. Departamento de Física, Universidade Federal de Minas Gerais, FW-01. Artifacts in magnetic measurements of magnetic fluid Belo Horizonte, Minas Gerais, Brazil samples. Z. Boekelheide1,2, I. Koltsova3 and C. Dennis21. Lafayette College, Easton, PA; 2. Material Measurement FW-10. Magnetite nanoparticle coated snowman-like PMMA Laboratory, NIST, Gaithersburg, MD; 3. Montgomery College, microbeads and their magnetorheological response.Y. Liu1,2 Germantown, MD and H. Choi11. Department of Polymer Science and Engineering, Inha Univ, Incheon, Republic of Korea; 2. State Key Laboratory FW-02. High Shear Rate Flow in a Linear Stroke Magnetorheological of Metastable Materials Science and Technology, Yanshan Energy Absorber. W. Hu 1, N.M. Wereley1, G. Ngatu2 and University, Qinhuangdao, China G.J. Hiemenz21. Dept. of Aerospace Engineering, University of Maryland, College Park, MD; 2. Techno-Sciences Inc., Greenbelt, FW-11. Magnetorheological Damper with a Spiral Channel Bypass MD Valve.G. McLaughlin1, W. Hu1 and N.M. Wereley11. Dept. of Aerospace Engineering, University of Maryland, College Park, FW-03. Self-assembly of graphene oxide wrapped soft magnetic MD carbonyl iron particles and their magnetorheology.W. Zhang1 1 and H. Choi 1. Department of Polymer Science and Engineering, FW-12. A Fail-Safe Magnetorheological Energy Absorber for Shock Inha Univ, Incheon, Republic of Korea and Vibration Isolation. X. Bai1 and N.M. Wereley21. Dept. of Automotive Engineering, Hefei University of Technology, Hefei, FW-04. Simulations of Magnetorheological Fluids Beyond the Chain- Anhui, China; 2. Dept. of Aerospace Engineering, University of Based Shear Limit. S.G. Sherman1 and N.M. Wereley11. Dept. of Maryland, College Park, MD Aerospace Engineering, University of Maryland, College Park, MD

FW-05. Characteristics of Temperature Rise in Variable Inductor Employing Magneto-rheological Fluid Driven by High Frequency Pulsed Voltage Source.H. Lee1, H. Cha1, D. Kim1 and S. Lee11. School of Electrical Eng. and Computer Science, Kyungpook National Univ., Daegu, Republic of Korea 230 PROGRAM PROGRAM 231

THURSDAY PLAZA BALLROOM A FX-08. Structural and Magnetic Properties of Epitaxial L21 Heusler 1,2 2 1 2 Alloy Fe2Cr0.5Co0.5Si. Y. Wang , G. Han , H. Lu , J. Qiu , AFTERNOON 2 2 1 2:30 Q. Yap , J. Sze and K. Teo 1. Electrical and Computer Engineering, National University of Singapore, Advanced Memory Lab, Singapore, Singapore; 2. Data Storage Institute, Session FX Agency for Science, Technology and Research (A*STAR)), SEMICONDUCTOR MAGNETISM II Singapore, Singapore (Poster Session) Nicholas Harmon, Chair FX-09. The Role of Chemical-Ordering on Spin-polarization of 1,2 1 2 Heusler Co2MnSi films. A. Kohn , N. Tal , D. Mogilianski , A. Kovács3, H. Naganuma4, S. Tsunegi4, M. Oogane4 and FX-01. Magnetic Schottky junctions using heterostructures of half- Y. Ando41. Department of Materials Engineering, Ben Gurion 1 metallic Co2MnSi/diamond semiconductors. K. Ueda , University of the Negev, Beer-Sheva, Israel; 2. Ilse Katz Institute 1 1 1 1 T. Soumiya , M. Nishiwaki , K. Kawamoto , T. Miyawaki and for Nanoscale Science and Technology, Ben Gurion University of 1 H. Asano 1. Graduate School of Engineering, Nagoya University, the Negev, Beer-Sheva, Israel; 3. Ernst Ruska-Centre for Nagoya, Japan Microscopy and Spectroscopy with Electrons and Peter Grünberg Institute, Forschungszentrum Jülich, Jülich, Germany; 4. FX-02. Electrically-induced modulation of transport and magnetic Graduate School of Engineering, Tohoku University, Sendai, 1 Japan properties in Au/Fe2O3/Pt heterustructure.Y. Chao , C. XueGang1, F. JianBo1, L. GuiJun1, Z. Yan1, L. ShunQuan1 and Y. JinBo11. School of Physics, Peking University, Beijing, China FX-10. Structural and Magnetic Optimisation of Co2FeSi Polycrystalline Thin Films Using Cr/Ag buffer layers.J. Sagar1, 1 2,3 FX-03. Giant tunnel magnetoresistance in fully epitaxial N.C. Yu and A. Hirohata 1. Physics, The University of York, York, North Yorkshire, United Kingdom; 2. Electronics, The Co2(Mn,Fe)Si/MgO/Co2(Mn,Fe)Si magnetic tunnel junctions. T. Kawami1, H. Liu1, Y. Honda1, K.M. Ayele1, T. Uemura1, F. Shi2, University of York, York, North Yorkshire, United Kingdom; 3. P.M. Voyles2 and M. Yamamoto11. Graduate School of Presto, Japan Science and Technology Agency, Kawaguchi, Information, Hokkaido University, Sapporo, Hokkai-do, Japan; 2. Saitama 332-0012, Japan Department of Materials Science and Engineering, University of Wisconsin-Madison, Madison, WI

FX-04. Spin injection from a half-metal at finite temperatures. THURSDAY PLAZA BALLROOM BC K.D. Belashchenko1, J.K. Glasbrenner1 and A.L. Wysocki11. Department of Physics and Astronomy, University of Nebraska- EVENING Lincoln, Lincoln, NE 6:00

Session ZA FX-05. Thin film synthesis of the semiconducting Heusler compound Fe2TiSi. M. Meinert1, M.P. Geisler1, J.M. Schmalhorst1, EVENING SESSION: SKRYMIONS AND THE C. Sterwerf1 and G. Reiss11. Physik, Universität Bielefeld, SPIN HALL EFFECT, WHAT ARE THEY GOOD Bielefeld, Germany FOR? Suzanne te Velthuis, Chair FX-06. Half-metallic 2-D epitaxial Fe3O4 thin films grown on epi- TiN/Si(100).A. Kumar1, S. Chaudhary1 and D. Pandya11. Physics Department, Indian Institute of Technology Delhi, New Delhi, 6:00 India ZA-01. Spin-orbitronics. (Invited) A. Fert11. CNRS/Thales, University Paris-Sud, Palaiseau, France FX-07. Magnetic, Magnetooptical and Magnetotransport Properties 1 2,3 of Co2(Fe,Ti)Ga Thin Films. V. Khovaylo , V. Rodionova , K. Chichay2, E. Gan’shina3, G. Zykov3, M. Ohtsuka4, R.Y. Umetsu5, A. Okubo6 and R. Kainuma61. National University of Science and Technology “MIS&S”, Moscow, Russian Federation; 2. Immanuel Kant Baltic Federal University, Kaliningrad, Russian Federation; 3. Faculty of Physics, Lomonosov Moscow State University, Moscow, Russian Federation; 4. Institute of Multidisciplinary Research for Advanced Materials, Tohoku University, Sendai, Japan; 5. Institute for Materials Research, Tohoku University, Sendai, Japan; 6. Department of Materials Science, Graduate School of Engineering, Tohoku University, Sendai, Japan 232 PROGRAM PROGRAM 233

FRIDAY PLAZA BALLROOM BC FRIDAY PLAZA BALLROOM F MORNING MORNING 8:30 8:30

Session GA Session GB SYMPOSIUM ON EMERGENT PHENOMENA VOLTAGE CONTROL OF ANISOTROPY, IN MAGNETISM MAGNETORESISTANCE II Stephen Hill, Chair Pavel Lukashev, Chair

8:30 8:30 GA-01. Spin ice, Monopoles and Magnetricity. (Invited) S. Bramwell11. GB-01. Voltage-controlled domain wall traps in ferromagnetic London Centre for Nanotechnology and Department fo Physics nanowires. U. Bauer1, S. Emori1 and G. Beach11. Materials and Astronomy, UCL, London, United Kingdom Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA 9:06 8:42 GA-02. Observation and manipulation of skyrmions in multiferroics. (Invited) S. Seki1,21. Department of Applied Physics, University of GB-02. Evaluation of voltage-torque by voltage-induced Tokyo, Tokyo, Japan; 2. PRESTO, Japan Science and Technology ferromagnetic resonance in CoFeB|MgO magnetic tunnel Agency, Tokyo, Japan junctions. Y. Shiota1,2, S. Miwa1,2, F. Bonell1,2, N. Mizuochi1,2, T. Shinjo1 and Y. Suzuki1,21. Osaka Univ Grad Schl Eng, Toyonaka, Osaka, Japan; 2. JST-CREST, Kawaguchi, Saitama, 9:42 Japan GA-03. Emergent spin electromagnetism induced by magnetization textures in the presence of spin-orbit interaction. (Invited) 8:54 G. Tatara11. RIKEN CEMS, Wako, Japan GB-03. Withdrawn 10:18 9:06 GA-04. Experimental Realization of a Quantum Spin Liquid Material. (Invited) T. Han1,21. Physics and James Franck GB-04. Parametric excitation of spin waves in thin films by electric Institute, University of Chicago, Chicago, IL; 2. Materials field.R.V. Verba1, V.S. Tiberkevich2, I.N. Krivorotov3 and Science Division, Argonne National Laboratory, Argonne, IL A.N. Slavin21. Faculty of Radiophysics, Taras Shevchenko National University of Kyiv, Kyiv, Ukraine; 2. Department of Physics, Oakland University, Rochester, MI; 3. Department of 10:54 Physics, University of California, Irvine, CA GA-05. Anomalous thermodynamic response in novel S=1/2 and S=1 frustrated magnetic systems. (Invited) L. Balicas11. Condensed 9:18 Matter Sciences, National High Magnetic Field lab, Tallahassee, FL GB-05. Control of depinning fields in nanowires using induced uniaxial anisotropy. D. Parkes1, R.P. Beardsley1, S.R. Bowe1,2, M. Wang1, A.C. Irvine3 and A.W. Rushforth11. School of Physics and Astronomy, University of Nottingham, Nottingham, United Kingdom; 2. Diamond Light Source, Didcot, Oxfordshire, United Kingdom; 3. Microelectronics Research Centre, University of Cambridge, Cambridge, United Kingdom

9:30 GB-06. Giant reversible electric-field-induced magnetic anisotropy switching with patterned electrodes on strain-mediated Ni thin film/PZT heterostructure. J. Cui1, J.L. Hockel1, D.M. Pisani1, P.K. Nordeen1, G.P. Carman1 and C.S. Lynch11. Mechanical and Aerospace Engineering Department, University of California, Los Angeles, Los Angeles, CA 234 PROGRAM PROGRAM 235

9:42 11:06 GB-07. Maximizing the perpendicular magnetic anisotropy in GB-14. Spin and symmetry properties of the buried Co2MnSi/MgO Fe|MgO magnetic tunnel junctions by impurities addition: interface. R. Fetzer1, Y. Ohdaira2, H. Naganuma2, M. Oogane2, Ab-initio calculations. A. Hallal1, B. Dieny1 and M. Chshiev11. Y. Ando2, T. Taira3, T. Uemura3, M. Yamamoto3, M. Aeschlimann1 SPINTEC, CEA|CNRS|UJF-Grenoble-1, INAC, 17 rue des and M. Cinchetti11. Department of Physics and Research Center Martyrs, 38054, Grenoble, France OPTIMAS, University of Kaiserslautern, Kaiserslautern, Germany; 2. Department of Applied Physics, Graduate School of Engineering, Tohoku University, Sendai, Japan; 3. Division of 9:54 Electronics for Informatics, Hokkaido University, Sapporo, Japan GB-08. Electric-field induced manipulation of the magnetic 1 1 anisotropy using SP-STM. S. Krause , A. Sonntag , 11:18 A. Schlenhoff1, J. Hermenau1, J. Friedlein1 and R. Wiesendanger11. Institute of Applied Physics, University of GB-15. First evidence of Domain’s duplication in perpendicular Hamburg, Hamburg, Germany Magnetic Tunnel Junctions. M. Bersweiler1, K. Dumesnil1, D. Lacour1, G. Lengaigne1 and M. Hehn11. Institut Jean Lamour, Vandoeuvre-lès-Nancy Cedex, France 10:06 GB-09. Voltage Control of Magnetization in Single Phase Hexaferrite Materials. K. Ebnabbasi1, M. Mohebbi1, H. Izadkhah1 and C. Vittoria11. Northeastern University, Boston, MA FRIDAY PLAZA BALLROOM E 10:18 MORNING 8:30 GB-10. Simultaneous magnetoresistance and magneto-optical measurements of domain wall properties in nanodevices. A. Beguivin1, H. Corte-Leon2, R.P. Cowburn1 and O. Kazakova21. Session GC Cavendish Laboratory, University of Cambridge, Cambridge, SPIN PUMPING, SPIN TRANSFER AND SPIN United Kingdom; 2. Quantum Detection Group, National Physical INJECTION Laboratory, Teddington, United Kingdom Mathias Klaeui, Chair

10:30 8:30 GB-11. Thermally assisted domain wall generation in perpendicular 1 1 GC-01. Spin Pumping due to Traveling Spin Waves in Yttrium Iron anisotropy trilayer nanowires. K. Narayanapillai , X. Qiu , 1 1 1 1 1 Garnet Thin Films. P. Janantha , Y. Sun , H. Chang and J. Rhensius and H. Yang 1. Department of Electrical and 1 Computer Engineering, National University of Singapore, M. Wu 1. Physics, Colorado State University, Fort Collins, CO Singapore, Singapore 8:42 10:42 GC-02. Pure Spin Current Generation via Magnetic Dynamics: Spin 1 Pumping in all-epitaxial FM/Insulator/NM Heterostructures. GB-12. Electric Control of Exchange Bias Training. W. Echtenkamp 1 1 1 1 1 1 1 Y. Pu , H. Wang , C. Du , R. Adur , A. Berger , A. Hauser , and C. Binek 1. Physics & Astronomy, University of Nebraska- 2 2 1 1 Lincoln, Lincoln, NE R. Williams , D. McComb , E. Johnston-Halperin , P.C. Hammel and F. Yang11. Physics, The Ohio State University, Columbus, OH; 2. Materials Science and Engineering, The Ohio State 10:54 University, Columbus, OH GB-13. Magnetoresistance effect of perpendicularly magnetized tetragonal- or cubic- Mn-Co-Ga Heusler alloy electrode. 8:54 T. Kubota1, S. Mizukami1, H. Naganuma2, M. Oogane2, Y. Ando2 1 GC-03. Spin pumping in Fe/Pd and Fe/Au/Pd heterostructures. and T. Miyazaki 1. WPI Advanced Institute for Materials E. Montoya1 1 1 Research, Tohoku university, Sendai, Miyagi, Japan; 2. , E. Girt and B. Heinrich 1. Department of Physics, Department of Applied Physics, Tohoku University, Sendai, Simon Fraser University, Burnaby, BC, Canada Miyagi, Japan 9:06 GC-04. Experimental test of the spin mixing interface conductivity concept. (Invited) M. Weiler1,21. Electromagnetics Division, National Institute of Standards and Technology, Boulder, CO; 2. Walther-Meissner-Institut, Bayerische Akademie der Wissenschaften, Garching, Germany 236 PROGRAM PROGRAM 237

9:42 10:54 GC-05. Spin-pumping spin injection into organic polymer GC-11. Electrical spin injection into graphene through monolayer h- PEDOT:PSS film. M. Kimata1, D. Nozaki1, Y. Niimi1, Y. Otani1,2 BN tunnel barrier. R. Moriya1, Y. Inoue1, T. Yamaguchi1, and H. Tajima31. Institute for Solid State Physics, University of S. Masubuchi1,2, S. Morikawa1, M. Onuki1, K. Watanabe3, Tokyo, Kashiwa, Chiba, Japan; 2. Center for Emergent Matter T. Taniguchi3 and T. Machida1,21. Institute of Industrial Science, Science (CEMS), RIKEN, Wako, Saitama, Japan; 3. Department University of Tokyo, Tokyo, Japan; 2. INQIE, University of Tokyo, of Material Science, University of Hyogo, Kamigori-cho, Ako- Tokyo, Japan; 3. National Institute for Materials Science, gun, Hyogo, Japan Tsukuba, Japan

9:54 11:06 GC-06. Spin-torque switching efficiency and its size-dependence in GC-12. Role of MgO barriers for spin and charge transport in CoFeB-MgO based tunnel junctions. J. Sun1, S.L. Brown1, Co/MgO/graphene non-local spin-valve devices.F. Volmer1,2, W. Chen3, E.A. Delenia2, M.C. Gaidis1, J. Harms3, G. Hu1, M. Drögeler1,2, E. Maynicke1,2, N. von den Driesch1,2, X. Jiang2, R. Kilaru1, W. Kula3, G.P. Lauer1, L.Q. Liu1, M.L. Boschen1,2, G. Güntherodt1,2 and B. Beschoten1,21. II. S. Murthy3, J.J. Nowak1, E. O’Sullivan1, S.S. Parkin2, Institute of Physics, RWTH Aachen University, Aachen, Germany; R.P. Robertazzi1, P.M. Rice2, G. Sandhu3, T. Topuria2 and 2. JARA-Fundamentals of Future Information Technology, Jülich- D.C. Worledge11. IBM Research, Yorktown Heights, NY; 2. IBM Aachen Research Alliance, Germany Almaden Research Center, San Jose, CA; 3. Micron Technologies, Boise, ID 11:18

10:06 GC-13. Individual atomic-scale magnets interacting with spin- polarized field-emitted electrons. A. Schlenhoff1, S. Krause1, GC-07. Electric field control of spin transfer torque in multiferroic A. Sonntag1 and R. Wiesendanger11. Institute of Applied Physics, tunnel junctions. A. Useinov1, A. Kalitsov2, J. Velev2 and University of Hamburg, Hamburg, Germany N. Kioussis11. Department of Physics, California State University, Northridge, CA; 2. Department of Physics, University of Puerto Rico, San Juan, Puerto Rico

10:18 FRIDAY PLAZA BALLROOM D MORNING GC-08. State diagrams of orthogonal spin transfer magnetic random 8:30 access memory devices. G. Wolf1, A.D. Kent1, B. Kardasz2 and M. Pinarbasi21. Department of Physics, New York University, New York, NY; 2. Spin Transfer Technologies, West Fremont, CA Session GD MAGNETO-OPTIC AND NEW MAGNETIC 10:30 MATERIALS II GC-09. Anisotropy engineering for ultrafast perpendicular STT- Haifeng Ding, Chair MRAM performance. D. Apalkov1, A. Khvalkovskiy1, R. Chepulskyy1, V. Nikitin1 and M. Krounbi11. Samsung 8:30 Electronics, Semiconductor R&D (New Memory Technology), Milpitas, CA GD-01. Engineered materials for all-optical helicity-dependent magnetic switching. (Invited) S. Mangin1,2, M. Gottwald2, C. Lambert1, D. Steil3, L. Pang4, M. Hehn1, S. Alebrand3, 10:42 M. Cinchetti3, G. Malinowski5, S. Fainman4, M. Aeschlimann3 2 GC-10. Chiral magnetic domain walls under weak and strong and E.E. Fullerton 1. Institut Jean Lamour - P2M, Universite de 1 Lorraine, Vandoeuvre-les-Nancy, France; 2. CMRR, University of interfacial Dzyaloshinkii-Moriya interactions. S. Emori , 1 1 2 1 1 California San Diego, La Jolla, CA; 3. Research Center U. Bauer , S. Ahn , E. Martinez , P. Agrawal , D.C. Bono and 1 OPTIMAS, University of Kaiserslautern,, kaiserlautern, G.S. Beach 1. Materials Science and Engineering, MIT, Germany; 4. Department of Electrical and Computer Cambridge, MA; 2. Applied Physics, University of Salamanca, Engineering, University of California San Diego, La Jolla, CA; 5. Salamanca, Spain Laboratoire de Physique des solides, University of Université Paris-Sud, Osay, France 238 PROGRAM PROGRAM 239

9:06 10:30 GD-02. High frequency magnetooptic vector magnetometry using GD-09. Emergence of Magnetism in Graphene by means of Magnetic AlN/Fe/AlN nanostructures. E.L. Jakubisova1, S. Visnovsky1, Insulator Proximity.H. Yang1, A. Hallal1, D. Terrade1, P. Siroky2, D. Hrabovsky2, J. Pistora2, I. Harward3 and X. Waintal2, S. Roche3,4 and M. Chshiev11. SPINTEC, Z. Celinski31. Faculty of Mathematics and Physics, Charles Cea|CNRS|UJF-Grenoble-1, INAC, 17 rue des Martyrs,38054, University in Prague, Prague, Czech Republic; 2. Grenoble, France; 2. SPSMS-INAC-CEA, 17 rue des Martyrs, Nanotechnology Center, Technical University of Ostrava, 38054, Grenoble, France; 3. SPSMS-CIN2 (ICCN-CSIC) and Ostrava-Poruba, Czech Republic; 3. Center for Magnetism and Universitat Autonoma de Barcelona, Catalan Institute of Magnetic Nanostructures, University of Colorado at Colorado Nanotechnology, Campus de la UAB, ES-08193, Barcelona, Springs, Colorado Springs, CO Spain; 4. ICREA, Institucio Catalana de Recerca i Estudis Avancats, ES-08010, Barcelona, Spain 9:18 10:42 GD-03. Plasmon Resonance Enhancement of Faraday Rotation of LPE Grown Garnet Films Populated with Gold Nanoparticles GD-10. Collective magnetism of CeO2 nanoparticles - Giant orbital on the Film Surfaces. G.S. Lang1, D. Bowen1, C. Krafft2 and currents. M. Coey1, K. Ackland1, M. Venkatesan1 and S. Sen11. I.D. Mayergoyz1,31. Electrical and Computer Engineering, Trinity College, Dublin, Ireland University of Maryland, College Park, College Park, MD; 2. Laboratory for Physical Sciences, College Park, MD; 3. Center of 10:54 Applied Electromagnetics, University of Maryland, College Park, MD GD-11. Magnetoresistance of monoaxial chiral helimagnet CrNb3S6 Y. Togawa1, Y. Kousaka2, J. Akimitsu2, S. Nishihara3, K. Inoue3, 4 5 9:30 A. Ovchinnikov and J. Kishine 1. N2RC, Osaka Prefecture University, Sakai, Osaka, Japan; 2. Dept. of Physics and GD-04. Temperature dependent magnetization reversal and Mathematics, Aoyama Gakuin University, Sagamihara, compensation points in ferrimagnetic GdFeCo films. J. Zhao1, Kanagawa, Japan; 3. Dept. of Chemistry, Hiroshima University, B. Youngblood2, I. Krivorotov2 and K.L. Wang11. Electrical Higashi-Hiroshima, Hiroshima, Japan; 4. Dept. of Physics, Ural Engineering, University of California, Los Angeles, Los Angeles, Federal University, Ekaterinburg, Russian Federation; 5. CA; 2. Physics and Astronomy, University of California, Irvine, Graduate School of Arts and Sciences, The Open University of Irvine, CA Japan, Chiba, Chiba, Japan

9:42 11:06 GD-05. A nonreciprocal ring resonator based on vacuum-annealed GD-12. Synthesis and Magnetic Properties of Single Phase magnetooptical cerium-substituted yttrium iron garnet. Titanomagnetites. X. Liu1, W. Schoenthal1, T. Cox1, T. Goto1, N. Sagara2, V. Singh1, M. Inoue2, L.C. Kimerling1 and M. McHenry1, A. Wise1, M. Diaz Michelena2, M. Maicas2 and C.A. Ross11. Massachusetts Institute of Technology, Cambridge, J. Mesa Una21. Materials Science Department, Carnegie Mellon MA; 2. Toyohashi University of Technology, Toyohashi, Aichi, University, Pittsburgh, PA; 2. Payloads Technologies and Space Japan Sciences Department, Instituto Nacional de Técnica Aeroespacial(INTA), Madrid, Spain 9:54 11:18 GD-06. Magneto-Optical Garnets on Semiconductor Substrates With Phase purity and High Faraday Rotation. A. Block1, P. Dulal1 GD-13. d° Magnetism, and Band Gap Engineering in rf-sputtered and B. Stadler11. University of Minnesota, Minneapolis, MN ZnO, MgO, Mg@ZnO Thin Films (1). M.K. Sreekanth2,1 and K.V. Rao1,21. Dept. of Materials Science, Royal Institute of Technology, Stockholm, Sweden; 2. Royal Institute of Technology, 10:06 Stockholm, Sweden

GD-07. Anisotropic magnetism in La0.75Pr0.25Co2P2 probed by transverse susceptibility and magnetocaloric effect.P.J. Lampen1, M. Phan1, P. Chai2, M. Shatruk2 and H. Srikanth11. Department of Physics, University of South Florida, Tampa, FL; 2. Department of Chemistry and Biochemistry, Florida State University, Tallahassee, FL

10:18

GD-08. Perpendicular magnetic anisotropy of Mn4N films on 1 1 1 1 SrTiO3(001). Y. Yasutomi , K. Ito , T. Sanai , K. Toko and T. Suemasu11. Institute of Applied Physics, University of Tsukuba, Tsukuba, Ibaraki, Japan 240 PROGRAM PROGRAM 241

FRIDAY GOVERNOR’S SQ 14 9:30 MORNING GE-06. The temperature dependence of magnetic vortices. E. Östman1, 8:30 E. Melander1, U.B. Arnalds1, V. Kapaklis1, M. Verschuuren2, G.K. Palsson3, A. Saw3, M.S. Brewer4, F. Kronast5, T.A. Hase4, Session GE C.S. Fadley3 and B. Hjörvarsson11. Department of Physics and MAGNETIC PATTERNED FILMS II Astronomy, Materials Physics, Uppsala, Sweden; 2. Philips Research Laboratories, Eindhoven, Netherlands; 3. Department Brian Maranville, Chair of Physics, University of California at Davis, Davis, CA; 4. Department of Physics, University of Warwick, Coventry, United 8:30 Kingdom; 5. Helmholtz Zentrum Berlin für Materialien und Energie, Berlin, Germany GE-01. Growth and Structural Studies of Fe islands deposited onto Antiferromagnetic Mn3N2(001) Nanopyramids. J. Pak1, A. Mandru1 and A.R. Smith11. Nanoscale and Quantum 9:42 Phenomena Institute, Physics and Astronomy, Ohio University, GE-07. Direct Experimental Study of Patterned Nanomagnetic Film Athens, OH Reversal. R. Shull1, Y. Kabanov2, A. Chen1, C. Dennis1, V. Gornakov2 and V. Nikitenko1,21. National Institute of Standards 8:42 and Technology, Gaithersburg, MD; 2. Institute of Solid State Physics, RAS, Chernogolovka, Russian Federation GE-02. Co/Pd Interface Anisotropy Formed by Microscopic Patterns. Y. Nam1 and S. Lim2,11. Department of Nano Semiconductor Engineering, Korea University, Seoul, Republic of Korea; 2. 9:54 Department of Materials Science and Engineering, Korea GE-08. Structural, chemical, and magnetic characteristics of University, Seoul, Republic of Korea nanomagnet arrays generated by phase transformation of oxide/metal superlattices with low-energy protons. S. Kim1, 1 1 8:54 S. Lee and J. Hong 1. Materials Science and Engineering, Yonsei University, Seoul, Republic of Korea GE-03. Magnetic coupling in hard/soft Co/Py bilayer antidot arrays.K.J. Merazzo1,2, G. Badini Confalonieri1, M. Vazquez1 and R. Perez del Real11. ICMM, Madrid, Madrid, Spain; 2. SPINTEC, 10:06 Grenoble, France GE-09. Magnetic Degradation of Exchange Biased Thin Films during Ion Milling. J.C. Read1, P.M. Braganca1, N. Robertson1 and 1 9:06 J.R. Childress 1. San Jose Research Center, HGST, San Jose, CA

GE-04. Static and Dynamic Magnetic Properties of Ni80Fe20 Anti-Ring Nanostructures. J. Ding1, N. Singh2, M. Kostylev3 and 10:18 1 A.O. Adeyeye 1. Department of Electrical and Computer GE-10. Compensation of Orange-peel Coupling Effect in MTJ Free Engineering, National University of Singapore, Singapore, Layer via Shape Engineering for NML Applications. Singapore; 2. Institute of Microeletronics, Singapore, Singapore; F.A. Shah1, V.K. Sankar1, P. Li1, G. Csaba1, E. Chen2 and 3. School of Physics, University of Western Australia, Crawley, G.H. Bernstein11. Electrical Engineering, University of Notre WA, Australia Dame, Notre Dame, IN; 2. Grandis, Inc., Milpitas, CA

9:18 10:30 GE-05. Control of vortex state formation in asymmetric magnetic GE-11. Sub-100 nm Magnetic Wires with Low Edge Roughness made 1 2 3 2 nanodisks.M. Im , A. Vogel , J. Hong , G. Meier and with a Bilayer Resist Electron Beam Lithography Process. 1 P. Fischer 1. CXRO, LBNL, Berkeley, CA; 2. Inst. Appl. Phys and S.A. Siddiqui1, J. Currivan2,3, S. Ahn4, G. Beach4, M.A. Baldo1 Center for Microstructure Research, U Hamburg, Hamburg, and C.A. Ross41. Electrical Engineering and Computer Science, Germany; 3. Dept. Emerging Mat. Sci., DGIST, Daegu, Republic Massachusetts Institute of Technology, Cambridge, MA; 2. of Korea Physics, Harvard University, Cambridge, MA; 3. Physics, Massachusetts Institute of Technology, Cambridge, MA; 4. Materials Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA 242 PROGRAM PROGRAM 243

10:42 9:06 GE-12. Size dependence of magnetic switching in perpendicular GF-04. Coercivity enhancement of hot-deformed Nd-Fe-B magnets by pillars close to the spin reorientation grain boundary diffusion process. K. Hioki1, A. Hattori2 and transition.W. Stefanowicz1,4, L.E. Nistor1,2, S. Pizzini1, W. Kuch3, T. Iriyama11. Daido Corporate Research & Development Center, V. Nguyen1, G. Gaudin2, S. Auffret2, B. Rodmacq2 and J. Vogel11. Daido Steel Co., Ltd., Nagoya, Japan; 2. Automotive Material Institut Néel, CNRS and UJF, Grenoble, France; 2. SPINTEC, Solutions dept., Daido Steel Co., Ltd., Tokyo, Japan Grenoble, France; 3. Institut für Experimentalphysik, Freie Universität Berlin, Berlin, Germany; 4. Institute of Physics, 9:18 Polish Academy of Sciences, Warszawa, Poland GF-05. Microstructure and properties of the composite magnets of 1,2 10:54 Nd-Fe-B powders coated with CaF2 coating. L. Zheng , H. Xin2, W. Bi2, M. Zhu1 and W. Li11. Division of Functional GE-13. Influence of trench material and pillar height to the dipolar Materials Research, Central Iron & Steel Researh Institute, and exchange interactions in directly deposited bit patterned Beijing, China; 2. School of Equipment Manufacture, Hebei media.N. Thiyagarajah1, M. Asbahi2, B. Wu1, N. Yakovlev2, University of Engineering, Handan, Hebei, China J.K. Yang2 and V. Ng 11. Information Storage Materials Laboratory, Electrical and Computer Engineering Department, 9:30 National Univ Singapore, Singapore, Singapore; 2. Institute of Materials Research and Engineering, Singapore, Singapore GF-06. Magnetic and microstructural modification of the Nd-Fe-B 1 sintered magnet by mixed DyF3/DyHx powder doping. T. Kim , S. Lee1, H. Kim2, M. Lee3 and T. Jang31. Materials Science and Engineering, Korea University, Seoul, Republic of Korea; 2. R&D Center, Jahwa Electronics Co. Ltd., Cheongwon, Republic of FRIDAY GOVERNOR’S SQ 15 Korea; 3. Hybrid Engineering, Sunmoon University, Asan, MORNING Republic of Korea 8:30 9:42 Session GF GF-07. Magnetic properties of Sm-Fe-B melt-spun ribbons. T. Saito1 PERMANENT MAGNET PROCESSING II and D. Nishio-Hamane21. Chiba Institute of Technology, Chiba, Jeffrey Shield, Chair Japan; 2. Institute for Solid State Physics, The University of Tokyo, Kashiwa, Japan

8:30 9:54 GF-01. Mechanism of Shell Structure Formation by HRE Grain Boundary Diffusion Process of Sintered Nd-Fe-B Magnets. GF-08. The evolutions of coercivity and grain boundary chemistry of 1,2 U.M. Seelam1, T. Ohkubo1, T. Abe1, S. Hirosawa1 and K. Hono11. sintered Nd-Fe-B magnets with Ce addition. C. Yan , 1,2 1,2 1,2 1,2 Elements Strategy Initiative Center for Magnetic Materials S. Guo , R. Chen , D. Lee and A. Yan 1. Key Laboratory of (ESICMM), National Institute for Materials Science, Tsukuba, Magnetic Materials and Devices, Ningbo Institute of Material Ibaraki, Japan Technology and Engineering, Chinese Academy of Sciences, Ningbo, Zhejiang, China; 2. Zhejiang Province Key Laboratory of Magnetic Materials and Application Technology, Ningbo Institute 8:42 of Material Technology and Engineering, Chinese Academy of GF-02. Prospects for Improving Alnico Alloys. M.J. Kramer1, L. Zhou1, Sciences, Ningbo, Zhejiang, China R.W. McCallum1, S. Constantinides2 and I.E. Anderson11. Ames Laboratory, Iowa State University, Ames, IA; 2. Arnold Magnetic 10:06 Technologies, Rochester, NY GF-09. Effect of Fe content on structural and magnetic properties of 1,3 2,3 SmCo4-xFexB alloys. X. Jiang , B. Balamurugan and 8:54 J. Shield1,31. Department of Mechanical & Materials GF-03. Anisotropic hot deformed magnets prepared by Zn-coated Engineering, Univ. of Nebraska-Lincoln, Lincoln, NE; 2. MRE-Fe-B ribbon powder (MRE=Nd+Y+Dy). W. Tang 1, Department of Physics and Astronomy, Univ. of Nebraska- L. Zhou1, K.W. Sun1, K.W. Dennis1, M.J. Kramer1, I.E. Anderson1 Lincoln, Lincoln, NE; 3. Nebraska Center for Materials and and R.W. McCallum11. Ames Lab of DOE, Ames, IA Nanoscience, Univ. of Nebraska-Lincoln, Lincoln, NE 244 PROGRAM PROGRAM 245

10:18 8:42 GF-10. Fully-dense Mn-Al-C permanent magnets via hot pressing of GG-02. Magnetoimpedance of thin film meander with composite mechanically milled powder. M. Lucis1, M.S. Meyer3, coating layer containing Ni nanoparticles. K. Lodewijk1,2, F.E. Pinkerton3, S. Constantinides4 and J. Shield1,21. Mechanical E. Fernandez2, A. Garcia-Arribas2, G. Kurlyandskaya2, & Materials Engineering, Univ Nebraska-Lincoln, Lincoln, NE; V.N. Lepalovskij3, A.P. Safronov3,4 and B. Kooi11. Material 2. Nebraska Centerfor Materials and Nanoscience, University of Sciences, University of Groningen, Groningen, Groningen, Nebraska, Lincoln, NE; 3. General Motors Technical Center, Netherlands; 2. Dept Electricidad y Electronica, Universidad del Warren, MI; 4. Arnold Magnetic Technologies Corp, Rochester, Pais vasco UPH-EHU, Bilbao, Spain; 3. Ural Federal University, NY Ekaterinburg, Russian Federation; 4. Institute of Electrophysics, UD RAS, Ekaterinburg, Russian Federation 10:30 8:54 GF-11. Imprinting of fine-scale magnetic patterns in hard magnetic films using magnetic foil masks. O.D. Oniku1, P.V. Ryiz1, GG-03. Glancing Angle Deposition Induced Anisotropy and Its A. Garraud1, D. Le Roy2, N.M. Dempsey2 and D.P. Arnold11. Influence on Giant Magnetoimpedance Effect in Nife/Cu/Nife Electrical and Computer Engineering, University of Florida, Thin Films. B. Li1 and J. Kosel11. Computer, Electrical and Gainesville, FL; 2. Institut Néel, CNRS-UJF,, 25 rue des Martyrs Mathematical Sciences and Engineering Division, King Abdullah 38042, Grenoble, France University of Science and Technology, Thuwal, Saudi Arabia

10:42 9:06 GF-12. Nd-Fe-B nanoparticles through surfactant assisted mechanical GG-04. UHF Tuneable Compact Antennas with Co2Z Hexaferrite milling and alloy design. J. Bornhoft1 and J.E. Shield11. Substrate.Z. Chen1,2, X. Wang1, H. Lin1, Z. Zhou1, T. Nan1, Mechanical Engineering, University of Nebraska, Lincoln, NE C. Parini2 and N. Sun11. Electrical and Computer Engineering Department, Northeastern University, Boston, MA; 2. Electronic Engineering and Computer Science, Queen Mary University of 10:54 London, London, United Kingdom GF-13. Low temperature diffusion process of rare-earth copper eutectic alloy for hot-deformed Nd-Fe-B bulk magnets. 9:18 T. Akiya1, L. Liu1,2, H. Sepehri-Amin1, T. Ohkubo1, K. Hioki3, A. Hattori3 and K. Hono1,21. ESICMM, National Institute for GG-05. Finite element analysis of ferrite-cored inductor with DC bias Materials Science, Tsukuba, Japan; 2. Univ. Tsukuba, Tsukuba, current using an equivalent-circuit model of dynamic Japan; 3. Daido Steel Co., Ltd., Nagoya, Japan hysteretic property. S. Ito1, T. Mifune1, T. Matsuo1, M. Suzuki2 and K. Kawano21. Dept. Electrical Engineering, Kyoto University, Kyoto, Japan; 2. Taiyo Yuden Co., Ltd., Takasaki, Japan

FRIDAY GOVERNOR’S SQ 16 9:30 MORNING 8:30 GG-06. Performance Improvement of Magnetic Gear and Comparison with Conventional Mechanical Gear. K. Nakamura1, M. Fukuoka1 and O. Ichinokura11. Graduate Session GG School of Engineering, Tohoku University, Sendai, Japan SOFT MAGNET APPLICATIONS Hiroaki Kikuchi, Chair 9:42

GG-07. A magnetostrictive electric power generator. M. Trapanese1, 8:30 V. Franzitta1 and A. Viola11. DEIM, Università di Palermo, GG-01. Magnetic and magnetoimpedance studies on controlled Joule Palermo, Italy

annealed amorphous Co73Fe4.5Ni0.5Mn0.5Nb0.5Si4.2B16.8 alloy. 1 1 S.K. Manna and S. Veeturi 1. Physics, Indian Institute of 9:54 Technology Madras, Chennai, Tamilnadu, India GG-08. A Hybrid 3D-WPT Device Based on Adaptive Vector Control. J. Zhao1, X. Huang1 and W. Wang11. Southeast University, Nanjing, China 246 PROGRAM PROGRAM 247

10:06 8:54 ε GG-09. Ac loss reduction of rectangular busbars by covering their GH-03. Spin polarisation in strained epitaxial -Fe1-xCoxSi thin films. edges with low permeable magnetic caps. I. Sasada11. Applied P. Sinha1, N.A. Porter1 and C.H. Marrows11. Condensed Matter, Science for Electronics and Materials, kyushu University, Kasuga, University of Leeds, Leeds, United Kingdom Japan 9:06 10:18 GH-04. First principles simulations of band alignment of NiMnSb/III- GG-10. Novel Magnetic Material Shielding Approach for Reduction of V semiconductors heterostructures for spintronic End-Core Effect in Switched Reluctance Motor. A. Labak1, applications. A. Debernardi1, M. Peressi2 and A. Baldereschi21. C. Lai1, Y. Zheng1 and N. Kar11. University of Windsor, Windsor, CNR-IMM, uos Agrate Brianza, Agrate Brianza, Italy; 2. ON, Canada Universita’ di Trieste, Trieste, Italy

10:30 9:18 GG-11. Analysis of electromagnetic devices through Lie’s symmetries. GH-05. Non-symmetric Interfaces in Symmetric Mn-Deficient 1 1 2 L.T. Loureiro , A.F. Ferreira Fo. , J.S. Zabadal and Co2MnSi/MgO/Co2MnSi Magnetic Tunnel Junctions R.P. Homrich11. Electrical Engineering, Federal University of Investigated by High Resolution Scanning Transmission Rio Grande do Sul, Porto Alegre, Rio Grande do Sul, Brazil; 2. Electron Microscopy.F. Shi1, H. Liu2, M. Yamamoto2 and Mechanical Engineering, Federal University of Rio Grande do P. Voyles11. Materials Science and Engineering, University of Sul, Porto Alegre, Rio Grande do Sul, Brazil Wisconsin, Madison, Madison, WI; 2. Division of Electronics for Informatics, Hokkaido University, Sapporo, Japan

9:30 FRIDAY GOVERNOR’S SQ 12 GH-06. Investigation of grain boundary ferromagnetism in TM-doped MORNING In2O3 films made by PLD. G.A. Gehring1, Q. Feng1, 1 2 3 3 3 8:30 H.J. Blythe , S. Heald , F. Jiang , X. Qin , X. Xu and M.A. Fox11. Deoartment of Physics and Astronomy, U. of Sheffield, Sheffield, S. Yorkshire, United Kingdom; 2. 2. Session GH Advanced Photon Source, Argonne National Laboratory, Argonne, INTERFACE EFFECTS FOR MAGNETIC IL; 3. Key Laboratory of Magnetic Molecules and Magnetic SEMICONDUCTORS, HEUSLERS AND OTHER Information Materials of Ministry of Education and School of Chemistry and Materials Science, Shanxi Normal University, HALF-METALLICS Linfen, Shanxi, China Ezekiel Johnston-Halperin, Chair 9:42 8:30 GH-07. Atomic study of Co2FexMn1-xSi/Ag interface.P.J. Hasnip1, GH-01. Interface engineering of a magnetic oxide directly on silicon L. Lari1,2, K. Yoshida3,4, D. Gilks1, M. Oogane5, Y. Ando5, (001). C. Caspers1, S.D. Flade1, M. Gorgoi2, C.M. Schneider1,3 A. Hirohata6 and V.K. Lazarov11. Department of Physics, and M. Müller11. Peter Grünberg Institut (PGI-6), Research University of York, York, United Kingdom; 2. York-JEOL Center Jülich, Jülich, NW, Germany; 2. BESSY II, Helmholtz- Nanocentre, University of York, York, United Kingdom; 3. Zentrum Berlin für Materialien und Energie, Berlin, Germany; 3. Department of Crystalline Materials Science and Ecotopia CeNIDE, University Duisburg Essen, Duisburg, NW, Germany Science Institute, Nagoya University, Nagoya, Japan; 4. Nanostructures Research Laboratory, Japan Fine Ceramics Center, Nagoya, Japan; 5. Department of Applied Physics, 8:42 Graduate School of Engineering, Tohoku University, Tohoku, GH-02. Fe3O4 thin films with bulk like magnetic and Sendai, Japan; 6. Department of Electronics, University of York, magnetotransport behaviour. D. Gilks1, M. Kosuke3, York, United Kingdom J. Sizeland1, L. Lari1,4, H. Hosono3,2, T. Susaki3 and 1 V.K. Lazarov 1. Department of Physics, University of York, York, 9:54 United Kingdom; 2. Frontier Research Center, Tokyo Institute of Technology, Yokohama, Japan; 3. Secure Materials Center, GH-08. Ferromagnetic interfacial interaction and magnetic proximity Materials and Structures Laboratory, Tokyo Institute of effect in Co2FeAl/(Ga,Mn)As bilayer. J. Zhao11. State Key Technology, Yokohama, Japan; 4. York-JEOL Nanocentre, Laboratory For Superlattices And Microstructures, Institute of University of York, York, United Kingdom Semiconductors, Chinese Academy of Sciences, Beijing, China 248 PROGRAM PROGRAM 249

10:06 FRIDAY EXHIBIT HALL GH-09. The adsorption of h-BN monolayer on the Ni(111) surface by MORNING DFT-D calculations. X. Sun1,2, Z. Li1, M. Ohtomo3, S. Sakai3 and 9:30 Y. Yamauchi21. Department of Physics, University of Science and Technology of China, Hefei, China; 2. National Institute for Session GP Materials Science, Tsukuba, Japan; 3. Advanced Science VORTICES AND RINGS Research Center, Japan Atomic Energy Agency, Ibaraki, Japan (Poster Session) 10:18 Ferran Macia, Chair GH-10. Hexagonal Boron Nitride Tunnel Barrier for Spin Injection GP-01. Interactions of two-dimensional magnetic droplet solitons. into Graphene at Room Temperature. V. Mutta1, A. Dankert1, M.D. Maiden1,2, L. Bookman2 and M.A. Hoefer21. Meredith J. Bergsten1, T. Ive1 and S.P. Dash11. Department of College, Raleigh, NC; 2. Mathematics, North Carolina State Microtechnology and Nanoscience, Chalmers University of University, Raleigh, NC Technology, Göteborg, Sweden

GP-02. Dynamics of a magnetic vortex in the presence of interfacial 10:30 Dzyaloshinskii-Moriya interaction. J. Moon1 and K. Lee1,21. GH-11. MoS2 Field Effect Transistors with Ferromagnetic Tunnel Department of Materials Science and Engineering, Seoul, Contacts. A. Dankert1, L. Langouche1, M.V. Kamalakar1 and Republic of Korea; 2. KU-KIST Graduate School of Converging S.P. Dash11. Microtechnology and Nanoscience, Chalmers Science and Technology, Seoul, Republic of Korea University of Technology, Göteborg, Sweden GP-03. Efficient magnetic vortex circulation switching: the effect of 10:42 disk geometry and the rise time of magnetic field pulses.M. Urbanek2,3, V. Uhlir1,2, N. Eibagi1, J.J. Kan1, M. Im4, GH-12. Magnetotransport and Structural Properties of Thin Film P. Fischer4, R. Kalousek2,3, E.E. Fullerton1 and T. Sikola2,31. Spin Gapless Semiconductors. M.E. Jamer1, B.A. Assaf1, 1 1 Center for Magnetic Recording Research, University of T. Devakul and D. Heiman 1. Physics, Northeastern University, California, San Diego, La Jolla, CA; 2. CEITEC BUT, Brno Boston, MA University of Technology, Brno, Czech Republic; 3. Institute of Physical Engineering, Brno University of Technology, Brno, 10:54 Czech Republic; 4. Center for X-ray Optics, Lawrence Berkeley National Laboratory, Berkeley, CA GH-13. Influence of internal electronic transitions on spin injection into electronic states of Fe dopants in GaAs. V.R. Kortan1, C. Sahin1, J. Bocquel2, P.M. Koenraad2 and M.E. Flattè1,21. GP-04. Dynamics and statics of magnetic nanodisks strongly coupled Physics and Astronomy, University of Iowa, Iowa City, IA; 2. via a magnetostatic interaction: vortex and metastable flower 1 1 1 1 Applied Physics, Eindhoven University of Technology, Eindhoven, states. M. Albert , L. Fadahunsi , W. Wang , M. Bisotti , 1 1 2 1 Netherlands D. Chernychenko , M. Beg , P. Metaxas and H. Fangohr 1. Engineering and the Environment, University of Southampton, Southampton, United Kingdom; 2. School of Physics, University 11:06 of Western Australia, Crawley, WA, Australia GH-14. Magnetic phases and anisotropy in defective SiC. S. Zhou1, 1 1 1 1 Y. Wang , S. Prucnal , K. Potzger and M. Helm 1. Institute of Ion GP-05. Synchronization through dipolar coupling of two neighboring Beam Physics and Materials Research, Helmholtz-Zentrum spin transfer vortex oscillators.N. Locatelli1, V. Cros1, Dresden-Rossendorf, Dresden, Germany A. Hamadeh2, R. Lebrun1, V. Naletov2, G. De Loubens2, F. Abreu Araujo3, A. Belanovskiy4, J. Grollier1, S. Girod1, C. Deranlot1, 2 4 5 5 1 11:18 O. Klein , K. Zvezdin , J. Prieto , M. Muñoz and A. Fert 1. Unité Mixte de Physique CNRS/Thales, Palaiseau, France; 2. Service GH-15. Magnetism of doped oxide nanoparticles: Role of surfaces. de Physique de l’Etat Condensé, CEA, Gif sur Yvette, France; 3. P. Raghani1 and B. Ramanujam11. Physics, Boise State University, Université Catholique de Louvain, Louvain la Neuve, Belgium; 4. Boise, ID A.M. Prokhorov General Physics Institute, Moscow, Russian Federation; 5. Instituto de Microelectrónica de Madrid, CNM,CSIC, Madrid, Spain

GP-06. Dynamic decay of a single vortex into vortex-antivortex pairs. V. Novosad1 and S. Jain11. Materials Science Division, Argonne Nat Lab, Argonne, IL 250 PROGRAM PROGRAM 251

GP-07. Spin Motive Force Induced by Moving Vortex in Magnetic GP-15. Magnetic Reversal Modes in Systems of Interacting Fe Rings. Nanostructures. A. Gangwar1,2, H.G. Bauer1, M. Noske2, S. Castillo1,2, N. Vargas1,2, S. Allende1,2 and D. Altbir1,21. M. Weigand2, H. Stoll2, G. Schuetz2, G. Woltersdorf1 and Departamento de Física, Universidad de Santiago de Chile, C.H. Back11. University of Regensburg, Regensburg, Germany; 2. Santiago, Santiago, Chile; 2. Center for the Development of Max Plank Institute for Intelligent Systems, Stuttgart, Germany Nanoscience and Nanotechnology, Santiago, Santiago, Chile

GP-08. The phase locking of vortices in permalloy double disks GP-16. Skyrmion Tubes in MnSi Thin Films. S. Zhang1, A. Figueroa- medicated by exchange coupling.Q. Zheng1, Q. Zhu1, S. Zhang1, Garcia2, A.A. Baker1, G. Van Der Laan2, P. Steadman2 and X. Liu1, C. Mu1, . Wang1 and Q. Liu11. Key Laboratory for T. Hesjedal11. Condensed Matter Physics, University of Oxford, Magnetism and Magnetic Materials of the Ministry of Education, Oxford, United Kingdom; 2. Diamond Light Source, Didcot, Lanzhou, China United Kingdom

GP-09. Equilibrium position dependent magnetic vortex dip GP-17. Electrical Detection of a Skyrmion State in Sputter Deposited dynamics under rotating magnetic fields. J. Shim1, H. Piao2,3, MnSi Thin Films. B. Youngblood1 and I.N. Krivorotov11. S. Lee1 and D. Kim11. Department of Physics, Chungbuk National Department of Physics and Astronomy, University of California, University, Cheongju, Republic of Korea; 2. College of Science, Irvine, Irvine, CA China Three Gorges University, Yichang, China; 3. Key Laboratory of Advanced Materials, School of Materials Science and Engineering, Beijing, China

GP-10. Time-resolved PEEM imaging of vortex dynamics in an FRIDAY EXHIBIT HALL equilateral triangular arrangement of three magnetic disks. MORNING X. Wang1, D.J. Keavney2, D.J. Clarke3, O. Tchernyshyov4, 9:30 M. Asmat-Uceda5, K.S. Buchanan5, A. Melikyan6 and X.M. Cheng11. Department of Physics, Bryn Mawr College, Bryn Session GQ Mawr, PA; 2. Advanced Photon Source, Argonne National Laboratory, Argonne, IL; 3. Department of Physics, California MAGNETOCALORICS AND Institute of Technology, Pasadena, CA; 4. Department of Physics MAGNETOELASTICS II and Astronomy, Johns Hopkins University, Baltimore, MD; 5. (Poster Session) Department of Physics, Colorado State University, Fort Collins, CO; 6. American Physical Society, Ridge, NY Arcady Zhukov, Chair

GP-11. Selective mode detection in three-chained magnetic vortices. GQ-01. The magnetostriction and its ratio to hysteresis for Tb-Dy-Ho- 1 2 2 1 1 N. Hasegawa1, S. Sugimoto1, Y. Niimi1 and Y. Otani1,21. ISSP, Fe alloys. B. Wang , Y. Lv , G. Li , W. Huang , L. Weng and 3 University of Tokyo, Kashiwa, Japan; 2. RIKEN-CEMS, Wako, B. Cui 1. School of Electrical Engineering, Hebei University of Japan Technology, Tianjin, China; 2. School of Materials Science and Engineering, Hebei University of Technology, Tianjin, China; 3. Electron Energy Corporation, Landisville, PA GP-12. Magnetic vortex dynamics in thickness-modulated Ni80Fe20 disks. G. Shimon1,2, A.O. Adeyeye1,2 and C.A. Ross2,31. Electrical and Computer Engineering, National University of Singapore, GQ-02. Effect of Al substitution for Fe on magnetic and Singapore, Singapore; 2. Singapore-MIT Alliance, Singapore, magnetostrictive properties in Pr(AlxFe1-x)1.9 1,2 1 1 1 1 1 Singapore; 3. Materials Science and Engineering, Massachusetts alloys.Y. Tang , L. Chen , J. Gao , S. Zhang , J. Wei , S. Tang 1 Institute of Technology, Cambridge, MA and Y. Du 1. Nanjing National Laboratory of Microstructures, Jiangsu Provincial Laboratory for Nanotechnology and Department of Physics, Nanjing University, Nanjing, China; 2. GP-13. Investigation of magnetic anisotropy in spin vortex discs. College of Physics and Technology, Guangxi Normal University, 1 1 N. Garraud and D.P. Arnold 1. Electrical and Computer Guilin, GuangXi, China Engineering, University of Florida, Gainesville, FL

GP-14. Magnetic properties of cylindrical diameter modulated Ni80Fe20 nanowires: Interaction and coercive fields.M.S. Salem1,2, P. Sergelius2, R.M. Corona3, D. Goerlitz2, K. Nielsch2 and J. Escrig31. Physics Department, Cairo University, Giza, Egypt; 2. Institute of Applied Physics, University of Hamburg, Hamburg, Germany; 3. Departamento de Física, Universidad de Santiago Chile, Santiago, Chile 252 PROGRAM PROGRAM 253

GQ-03. Neutron diffraction study of MnNiGa2 - structural and GQ-10. Magnetic and martensitic phase transitions in Ni-Mn-In magnetic behaviour. J. Wang1,2, L. Ma4, M. Hofmann5, Based Thin Films. A. Sokolov1, L. Zhang1, R. Sabirianov2, S.J. Kennedy2, S.J. Campbell3, M.F. Md Din1, M. Hoelzel5,6, A. Quetz3, T. Samanta3, I. Dubenko3, S. Stadler4 and N. Ali31. G. Wu4 and S. Dou11. Institute for Superconducting & Electronic University Nebraska-LIncoln, Lincoln, NE; 2. University of Materials, University of Wollongong, Wollongong, NSW, Nebraska-Omaha, Omaha, NE; 3. Southern Illinois University at Australia; 2. Bragg Institute, ANSTO, Sydney, NSW, Australia; 3. Carbondale, Carbondale, IL; 4. Louisiana State University, Baton School of Physical, Environmental and Mathematical Sciences, Rouge, LA The University of New South Wales, Canberra, Canberra, ACT, Australia; 4. Institute of Physics, Chinese Academy of Science, GQ-11. Effect of Atomic Order on the Phase Transitions of Beijing, China; 5. FRM-II, Technische Universität München, Ni Mn In Melt-Spun Ribbons. F. Xu 1, W. Li1, Z. Liao1, München, Germany; 6. Fachbereich Materialwissenschaften, 50 35 15 X. Fei1 and S. Li21. School of Materials Science and Engineering, Technische Universität Darmstadt, Darmstadt, Germany Nanjing University of Science and Technology, Nanjing, Jiangsu, China; 2. College of Physical Science, Qingdao University,

GQ-04. Magnetic Properties of full Heusler Alloys Ni2MnGa1-xZx with Qingdao, Shandong, China Z = Sn or Zn. L.S. Barton1, R. Lazott1 and E.R. Marsten11. Physics, Rochester Institute Technology, Rochester, NY GQ-12. Ferromagnetism and magneto-transport properties of Mn0.92Ca0.08As thin film grown on Al2O3(0001) substrate. GQ-05. Magneto-optical spectroscopy of ferromagnetic shape- D. Dung1,2, D. Thiet1,2, D. Tuan1 and S. Cho11. Department of memory Ni-Mn-Ga alloy. M. Veis1, M. Zahradnik1, L. Beran1, Physics, University of Ulsan, Ulsan, 680-749, Republic of Korea; R. Antos1, O. Heczko2 and L. Straka31. Institute of Physics, 2. Department of General Physics, School of Engineering Charles University in Prague, Prague, Czech Republic; 2. Physics, Ha Noi University of Science and Technology,, Ha Noi, 1 Institute of Physics, ASCR, Prague, Czech Republic; 3. Aalto Dai Co Viet road, Viet Nam University School of Engineering, Laboratory of Engineering Materials, Aalto, Finland GQ-13. Magnetism of FeRh(001) thin films: Density functional study. S. Jekal1, O. Kwon1 and S. Hong11. Physics, University of Ulsan, GQ-06. Effect of substitution of In for Co on magnetostructural Ulsan, Republic of Korea

coupling and magnetocaloric effect in MnCo1-xInxGe compounds.R. Wu1, L. Bao1, F. Hu 1, J. Wang1, X. Zheng1, GQ-14. Magnetostrictions of Fe3O4 and CoFe2O4: A first-principles J. Sun1 and B. Shen11. State Key Laboratory of Magnetism, study. D. Odkhuu1,2, W. Yun1, N. Park2 and S. Hong11. Physics, Institute of Physics, Chinese Academy of Sciences, Beijing, China University of Ulsan, Ulsan, Republic of Korea; 2. Interdisciplinary School of Green Energy, Ulsan National Institute GQ-07. Magnetostructural transition and magnetocaloric effect in of Science and Technology, Ulsan, Republic of Korea 1,2 MnNiGe1.05 melt-spun ribbons. G.D. Pérez , J.L. Sanchez Llamazares2, P. Álvarez-Alonso3, R. Varga4 and V. Chernenko51. GQ-15. Ferri-to-ferro-magnetic and ferro-to-para-magnetic Instituto Tecnológico Superior de Irapuato (ITESI), Irapuato, transitions in Ni48Co2Mn35In13Ga2 Heusler alloy. Guanajuato, Mexico; 2. División de Materiales Avanzados, M. Ovichi1, M. Ghahremani1, E. Della Torre1, L.H. Bennett1, Instituto Potosino de Investigación Científica y Tecnológica A.C., F. Johnson2 and V. Srivastava21. Electrical and Computer San Luis Potosi, San Luis Potosi, Mexico; 3. Departamento de Engineering, George Washington University, Washington, DC; 2. Electricidad Electrónica, Universidad del País Vasco, Bilbao, GE Global Research, Niskayuna, NY Spain; 4. Institute of Physics, Faculty of Sciences,, University Pavol Jozef Šafárik, Kosice, Slovakia; 5. BC Materials & University of Basque Country, Bilbao, Spain

GQ-08. Composition and Crystallinity in Electrochemically Deposited FRIDAY EXHIBIT HALL 1 Magnetostrictive Galfenol (FeGa). E.C. Estrine and MORNING B.J. Stadler11. Electrical Engineering, University of Minnesota, Minneapolis, MN 9:30 Session GR GQ-09. Dynamics of the magneto-structural phase transition in INSTRUMENTATION AND BIO IMAGING La(Fe0.9Co0.015Si0.085)13 observed by magneto-optic imaging. M. Kuepferling1, C. Bennati1,2, F. Laviano2, G. Ghigo2 and (Poster Session) V. Basso11. National Institute of metrological research (INRIM), Justin Shaw, Chair Torino, Italy; 2. Department of Applied Science and Technology, Politecnico di Torino, Turin, Italy GR-01. A soft x-ray beamline for ps time-resolved x-ray magnetic circular dichroism. D.J. Keavney1 and R. Reininger11. Advanced Photon Source, Argonne National Laboratory, Argonne, IL 254 PROGRAM PROGRAM 255

GR-02. In-plane and out-of-plane vectorial magnetometry of CoFeTb GR-10. Combination of the Signal Space Separation Method with films measured by a multichromatic dual-beam Algebraic Reconstruction of Dipole-Quadrupole Source for magnetometer based on the magnetooptic Kerr effect using a Magnetoencephalography Inverse Problems. T. Nara1, triaxial magnetic field. T. Kuschel1, G. Götz1, Z. Kugler1 and K. Koiwa2, K. Inagaki1 and S. Ando11. Graduate School of G. Reiss11. Bielefeld University, Bielefeld, Germany Information Science and Technology, The University of Tokyo, Tokyo, Japan; 2. Graduate School of Informatics and Engineering, The University of Electro-Communications, Chofu, GR-03. Local hysteresis loops of magnetic nanostructures by field- Tokyo, Japan dependent MFM. M. Coisson1, G. Barrera1,2, F. Celegato1, E. Enrico1, A. Manzin1, P. Tiberto1 and F. Vinai11. Electromagnetics, INRIM, Torino, TO, Italy; 2. Dipartimento di GR-11. Magnetic Resonant Wireless Charger for Rechargering the Chimica, Università degli Studi di Torino, Torino, TO, Italy Deep Brain Stimulation. J. Wang1,2, J. Ruan1, K. Liu1 and M. Sun21. School of Electrical Engineering, Wuhan University, Wuhan, Hubei, China; 2. Neurological Surgery, University of GR-04. Measuring the inverse magnetostrictive effect in thin films Pittsburgh, Pittsburgh, PA using a vibrating sample magnetometer. B. Buford1, A. Jander1 and P. Dhagat11. Oregon State University, Corvallis, OR GR-12. Design of a biplanar triple-axis gradient coil system with a single-axis uniform magnetic field for ultra low field MRI. GR-05. Observation of Cobalt Thin Film Oxidation by Ballistic Y. Nakashima1,2 and J. Moreland11. NIST, Boulder, CO; 2. Kyushu Electron Emission Spectroscopy. G. Poulin1, M.S. Tan2, University, Fukuoka, Japan S.M. Wang1, J.K. Goh2, C. Troadec2 and V. Ng11. Information Storage Materials Laboratory, Electrical and Computer Engineering Department, National Univ Singapore, Singapore, GR-13. Ferromagnetic Resonance Spectroscopy of Single Nanorods in Singapore; 2. Institue of Materials Research and Engineering, a Microfluidic Device. A.L. Balk1,2, L.O. Mair1,2, F. Guo1,2, Singapore, Singapore C. Hangarter3, R.D. McMichael1, S.M. Stavis1 and J. Unguris11. Center For Nanoscale Science and Technology, National Institute of Standards and Technology, Gaithersburg, MD; 2. Maryland GR-06. Magnetic susceptibility and magnetic resonance measurement Nanocenter, University of Maryland, College Park, MD; 3. of the moisture content and hydration condition of magnetic Materials Science and Engineering Division, National Institute of mixture material. K. Tsukada1, T. Kusaka1, M.M. Saari1, Standards and Technology, Gaithersburg, MD K. Sakai1, T. Kiwa1 and Y. Bito21. The Graduate School of Natural Science and Technology, Okayama University, Okayama, Japan; 2. Central Research Laboratory, Hitachi Ltd., Kokubunji, GR-14. Large Surface Area and Low-External-Field Giant Japan Magnetoresistance Magnetic Biosensor. Y. Feng1, T. Klein1, L. Yu2, Y. Li1 and J. Wang11. Electrical and Computer Engineering, University of Minnesota, Minneapolis, MN; 2. GR-07. Modulation of Amplitude and Latency of Motor Evoked University of Science and Technology Beijing, Beijing, China Potential by Direction of Transcranial Magnetic Stimulation. A. Sato1,3, T. Torii1, Y. Itoh1, M. Iwahashi2 and K. Iramina31. Department of Medical Engineering, Junshin Gakuen University, Fukuoka, Japan; 2. Department of Medical Care and Welfare Engineering, Tokai University, Kumamoto, Japan; 3. Graduate School of Systems Life Sciences, Kyushu University, Fukuoka, FRIDAY EXHIBIT HALL Japan MORNING 9:30 GR-08. Deep Transcranial Magnetic Stimulation with Improved Focality using Square Coil Arrays.M. Lu1 and S. Ueno21. Key Session GS Lab. of Opt-Electronic Technology and Intelligent Control of MULTIFERROICS III: EFFECTS OF DOPING Ministry of Education, Lanzhou Jiaotong University, Lanzhou, China; 2. Department of Applied Quantum Physics, Graduate AND NANOCOMPOSITION School of Engineering, Kyushu University, Fukuoka, Japan (Poster Session) Eun Ju Moon, Chair GR-09. Development of Deep Brain and Focused Transcranial 1 Magnetic Stimulation Coil for Mice. R.L. Hadimani , GS-01. Structure and magnetic-electric properties of Co-doped 1 1 1 1 1 S.D. March , S. McAtee , K. Spoth , D.R. Stiner , L.J. Crowther polycrystalline TbMnO3.S. Wang1, P. Li 1, G. Wang1, D. Wu1, 1 and D.C. Jiles 1. Department of Electrical and Computer Y. Zou1, J. Shen1 and C. Cui11. Department of physics, Center for Engineering, Iowa State University, Ames, IA Optoelectronics Materials and Devices,Zhejiang Sci-Tech University, Hangzhou, China 256 PROGRAM PROGRAM 257

GS-02. Magnetic Properties of Epitaxial BiFeO3:BiMnO3 GS-11. Spin-glass effect and local microstructures in Zn-doped Nanocomposite Films on IBAD-TiN buffered Flexible YMnO3.A. Zhang1, G. Zhou2, C. Tang1 and X. Wu21. College of Hastelloy. J. Xiong1,2, H. Nestor2, V. Matias2, Q. Jia2, B. Tao1 and Science, Hohai University, Nanjing, China; 2. Department of Y. Li 11. State Key Lab of Electronic Thin Films and Integrated Physics, Nanjing University, Nanjing, China Devices, University of Electronic Science and Technology of China, Chengdu, China; 2. Division of Materials Physics and GS-12. Uncompensated antiferromagnetism in Ti-doped BiFeO3. Applications,, Los Alamos National Laboratory, Los Alamos, NM M. Garcia1, M.S. Bernardo1, T. Jardiel1, M. Peiteado1,2, M. Garcia-Hernandez3, F. Mompean3, A.C. Caballero1 and GS-03. Multiferroic fluctuations in Dy/Mn off-stoichiometric M. Villegas11. Electroceramics, Institute of Ceramics and Glass, DyMnO3.J. Wang1, Z. Zhao1, M. Liu1, Z. Yan1, S. Dong2 and Madrid, Madrid, Spain; 2. Applied Physics Department, J. Liu11. Department of Physics, Nanjing University, Nanjing, Universidad Politécnica de Madrid, Madrid, Madrid, Spain; 3. Jiangsu, China; 2. Department of Physics, Southeast University, Institute for Material Science, Madrid, Madrid, Spain Nanjing, China GS-13. Enhancement of magnetic properties on BiFeO3 ceramics by GS-04. Magnetoelectric response of AlN / [(Fe90Co10)78Si12B10 + Ba and Mn co-doping.H. Deng1,2, M. Zhang1, Q. Zhong1, J. Wei1 Terfenol-D] composite films. B. Tong1, X. Yang1, J. Ouyang1, and H. Yan11. College of Materials Science and Engineering, G. Lin1 and S. Chen11. Huazhong University of Science and Beijing University of Technology, Beijing, China; 2. School of Technology, Wuhan, China Science, Tianjin University of Technology and Education, Tianjin, China GS-05. Magnetic property and magnetoelectric effect in

Ba0.3Sr1.7Co2Fe12O22 single crystals observed by electron spin GS-14. Effects of Ho substitution on structure and magnetic 1 1 1 2 2 1 2 resonance. L. Yan , Y. Chai , Y. Sun , S. Chun , K. Shin and properties of BiFeO3 S. Pittala , D. Peram and K. Kim21. Institute of Physics, Chinese Academy of Sciences, S. Sanyadanam11. School of Physics, University of Hyderabad, Beijing, China; 2. Department of Physics and Astronomy, Seoul Hyderabad, Andhra Pradesh, India; 2. UGC-DAE Consortium for National University, Seoul, Republic of Korea Scientific Research, Mumbai, India

GS-06. Effects of Cr doping on the magnetic properties of GS-15. Ferromagnetic response of multiferroic TbMnO3 thin films 1 1 1 1 multiferroic YMnO3 T. Han , I. Wu and H. Hsu 1. Department mediated by epitaxial strain and chemical pressure.O. Morán , of Applied Physics, National University of Kaohsiung, Kaohsiung, J. Izquierdo1, A. Astudillo2, G. Bolanos2 and O. Arnache31. Taiwan Physics, national University of Colombia, Medellín, Antioquia, Colombia; 2. Physics, Universidad del Cauca, Popayan, Cauca, Colombia; 3. Physics, Universidad de Antioquia, Popayan, GS-07. Effect of diamagnetic barium substitution on magnetic and 1,2 Antioquia, Colombia photovoltaic properties in multiferroic BiFeO3 C. Tu , C. Hung1, Z. Xu2, L. Chang2, Y. Ting2 and D. Chiang31. Graduate Institute of Applied Science and Engineering, Fu Jen Catholic University, New Taipei City, Taiwan; 2. Physics, Fu Jen Catholic University, New Taipei City, Taiwan; 3. Teaching Center of Natural Sciences, Minghsin University of Science and Technology, FRIDAY EXHIBIT HALL Hsinchu, Taiwan MORNING 9:30 GS-08. Evidence of Magnetoelectric coupling on calcium doped bismuth ferrite thin films grown by chemical solution Session GT deposition. A.Z. Simões1, E. Longo1,2 and J.A. Varela1,21. MRAM AND MAGNETIC LOGIC DEVICES II Materials Science, UNESP-Faculty of Engineering, Guaratinguetá, São Paulo, Brazil; 2. Physics-Chemistry, UNESP- (Poster Session) Chemistry Institute, Araraquara, São Paulo, Brazil Jian-Ping Wang, Chair

GS-09. Effect of Sn substitution on structural, thermal and magnetic GT-01. Unidirectional transmission wire with asymmetrical dots for 1 1 1 properties in EuMn2O5. D. Kumar1, A.D. Thakur2, nanomagnetic logic gate. H. Nomura , A. Morita , S. Miura and 1 A. Tulapurkar1 and C.V. Tomy11. Department of Physics, Indian R. Nakatani 1. Osaka University, Suita City, Japan Institute of Technology Bombay, Mumbai, India; 2. School of Physics, Indian Institute of Technology Patna, Patna, India GT-02. Logic gate using hybrid magnetic tunnel junctions with normal and inverse tunneling magnetoresistive effect. 1,2 1 GS-10. Enhanced ferroelectric and magnetic properties of epitaxial S. Isogami and T. Oowada 1. General Education, Fukushima BiFeO3/BiMnO3 multiferroic heterostructures grown by National College of Technology, Iwaki, Fukushima, Japan; 2. sputtering.K. Singh1, A. Sharma1 and D. Kaur11. Department of Electronic Engineering, Tohoku Univeristy, Sendai, Miyagi, Japan Physics and Centre of Nanotechnology, Indian Institute of Technology Roorkee, Roorkee, Roorkee, India 258 PROGRAM PROGRAM 259

GT-03. Extraordinary Hall Balance. S. Zhang1, Y. Liu3, L.J. Collins- GT-12. Programmable Nanomagnetic Grids for Computing using 1 1 Mclntyre1, T. Hesjedal1, J. Zhang3, S. Wang2 and G. Yu31. Spin-transfer Nano-oscillators. S. Rajaram and S. Bhanja 1. Condensed Matter Physics, University of Oxford, Oxford, United university of south florida, Tampa, FL Kingdom; 2. State Key Laboratory of Magnetism, Institute of Physics, Beijing, China; 3. Department of Materials Physics, GT-13. Development of lateral spin valve devices for spin logic University of Science and Technology Beijing, Beijing, China applications. A. Klemm1, M. Jamali1, Y. Li2 and J. Wang11. Electrical and Computer Engineering, University of Minnesota, GT-04. Dramatic Reduction of Read Error through Pulse Width Saint Paul, MN; 2. Mechanical Engineering, Georgia Institute of Control in Spin Torque Random Access Memory. Z. Wang1, Technology, Atlanta, GA X. Wang1, H. Gan1, T. Lin1, Y. Zhou1, J. Zhang1 and Y. Huai11. Avalanche Technology, Fremont, CA GT-14. Dual functional memory cell structure by stacking multiple magnetic tunnel junctions.W. Kang1,2, W. Zhao1, Y. Zhang1, 1 2 1 1 GT-05. Modelling and Simulation Based Study of Spintronic Switches J. Klein , Y. Zhang , C. Chappert and D. Ravelosona 1. IEF, for Ultra Low Energy Global Interconnects and Clocking. CNRS, Univ. Paris-Sud, Paris, France; 2. Electronic and M. Sharad1 and K. Roy11. Purdue University, West Lafayette, IN Information Engineering, Beihang University, Beijing, China

GT-06. Fabrication and characterization of pseudo-spin-MOSFETs using a multi-project CMOS wafer. R. Nakane1,4, Y. Shuto2,4, 3,4 3,4 2,4 3,4 H. Sukegawa , Z. Wen , S. Yamamoto , S. Mitani , FRIDAY EXHIBIT HALL M. Tanaka1,4, K. Inomata3,4 and S. Sugahara2,41. Department of Electrical Engineering and Information Systems, The Univ. of MORNING Tokyo, Tokyo, Japan; 2. Imaging Science and Engineering 9:30 Laboratory, Tokyo Institute of Technology, Yokohama, Japan; 3. Magnetic Materials Center, National Institute for Materials Session GU Science, Tsukuba, Japan; 4. CREST, Japan Science and TUNNELING AND SPIN TRANSPORT II Technology Agency, Kawaguchi, Japan (Poster Session) GT-07. Spin-wave based realization of optical computing primitives. Zhong-Ming Zeng, Chair G. Csaba1, A. Papp1 and W. Porod11. University of Notre Dame, Notre Dame, IN GU-01. Dynamic Conductance and Tunneling Magnetoresistance Studies in Ion-beam Sputtered CoFeB/MgO/CoFeB Magnetic 1 1 GT-08. Interlayer exchange coupled free layer to increase PMA in Tunnel Junctions.B. Singh and S. Chaudhary 1. Physics CoFeB/MgO based p-MTJs. A. Singh1,2, O.N. Mryasov1,2 and Department, Indian Institute of Technology Delhi, New Delhi, S. Gupta2,31. Physics, University of Alabama, Tuscaloosa, AL; 2. India MINT Center, University of Alabama, Tuscaloosa, AL; 3. Metallurgical and Materials Engineering, University of Alabama, GU-02. Perpendicularly magnetized Heusler composite magnetic Tuscaloosa, AL materials and the spin filter effect in perpendicular magnetic tunnel junctions. Q. Ma1, S. Mizukami1, X. Zhang1, Y. Ando2 1 GT-09. Switching efficiency improvement in spin torque majority and T. Miyazaki 1. WPI Advanced Institute for Materials gates. D. Nikonov1, S. Manipatruni1 and I.A. Young11. Intel Research, Tohoku University, Sendai, Japan; 2. Applied Physics, Components Research, hillsboro, OR Graduate School of Engineering, Tohoku University, Sendai, Miyagi, Japan

GT-10. Trend of TMR and Variation in Vth for Keeping Data Load 1 GU-03. First-principles study of spin-polarized transport through π-π Robustness of MOS/MTJ Hybrid Latches. T. Ohsawa , 1 1 1 1,2 1,2 1,2 1,3 stacked paracyclophane molecules. L. Tao , D. Liu , S. Liang S. Ikeda , T. Hanyu , H. Ohno and T. Endoh 1. Center for 1 Spintronics Integrated Systems, Tohoku University, Sendai, Japan; and X. Han 1. Institute of Physics, Chinese Academy of Sciences, 2. Research Institute of Electrical Communication, Tohoku Beijing, China University, Sendai, Japan; 3. Center for Innovative Integrated Electronic Systems, Tohoku University, Sendai, Japan GU-04. Nonlinear thermal effect on sub-gigahertz ferromagnetic resonance in magnetic tunnel junction. S. Miwa1, Y. Fujii1, H. Kubota2, K. Yakushiji2, S. Ishibashi1, T. Saruya2, GT-11. Intermediate resistance states in p STT-MRAM cells. 2 2 1 S. Schäfer1, A. Khvalkovskiy1, D. Apalkov1, R.S. Beach1 and A. Fukushima , S. Yuasa and Y. Suzuki 1. Graduate School of V. Nikitin11. NMT, Samsung Electronics, Semiconductor R&D Engineering Science, Osaka University, Toyonaka, Osaka, Japan; Center, Milpitas, CA 2. Spintronics Research Center, National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Ibaraki, Japan 260 PROGRAM PROGRAM 261

GU-05. Tunnel Magnetoresistance Effect in Magnetic Tunnel GU-13. Enhanced tunnel magnetoresistance effect in an epitaxial γ Junctions using Fermi-Level-Tuned Epitaxial L21 Fe2Cr1- magnetic tunnel junction with a hybrid -Fe2O3/MgO barrier. 1,2 2 1 2 1,2 1,2 1,2 1,2 xCoxSi Heusler Alloy. Y. Wang , G. Han , H. Lu , J. Qiu , T. Nozaki , H. Kubota , A. Fukushima and S. Yuasa 1. Q. Yap2, J. Sze2 and K. Teo11. Electrical and Computer Spintronics Research Center, National Institute of Advanced Engineering, National University of Singapore, Advanced Industrial Science and Technology, Tsukuba, Ibaraki, Japan; 2. Memory Lab, Singapore, Singapore; 2. Data Storage Institute, CREST, JST, Kawaguchi, Saitama, Japan Agency for Science, Technology and Research (A*STAR)), Singapore, Singapore GU-14. Multi-valued tunneling magnetoresistance states realized in Fe/GaAlAs/GaMnAs trilayer structure. T. Yoo1, S. Lee1, GU-06. Tunneling Magnetoresistance of Perpendicular Magnetic X. Liu2, J. Furdyna2, D. Lee3 and E. Kim31. Physics department, Tunneling Junctions using L10-FePt Electrodes on Korea University, Seoul, Republic of Korea; 2. Physics MgO/CrRu/TiN Under-Layers. C. Kim1, J. Jung2, M. Sahashi2 department, University of Notre Dame, Notre Dame, IN; 3. and M. Kryder11. Electrical and Computer Engineering, Carnegie Department of Physics and Research Institute for Natural Mellon University, Pittsburgh, PA; 2. Electonic Engineering, Sciences, Hanyang University, Seoul, Republic of Korea Tohoku University, Sendai, Japan GU-15. Spin Transport in Normal Metal/Insulator/Topological GU-07. Material dependence of the tunneling magneto Seebeck effect: Insulator Coupled to Ferromagnetic Insulator Structures. Ab initio studies. C. Franz1, M. Czerner1 and C. Heiliger11. I. K. Kondo11. Research Institute for Electronic Science, Sapporo, Physikalisches Institut, Justus-Liebig-Universitaet Giessen, Japan Giessen, Germany

GU-08. Verwey transition effect on magneto-resistive coefficient on 1 Spinel ferrites XFe2O4 (X=Mn, Zn). L. Vazquez Zubiate , K.L. López Maldonado1, P. De la Presa2,3, J.A. Matutes Aquino4 FRIDAY EXHIBIT HALL and J.T. Elizalde Galindo11. Dpto. de Física y Matemáticas, MORNING Instituto de Ingeniería y Tecnología, Universidad Autónoma de 9:30 Ciudad Juárez, Juárez, Chihuahua, Mexico; 2. Instituto de Magnetismo Aplicado, UCM-ADIF-CSIC, Las Rozas, Madrid, Session GV Spain; 3. Dpto. de Física de Materiales, Universidad Complutense de Madrid, Madrid, Madrid, Spain; 4. Centro de RARE EARTH-FREE PERMANENT Investigación en Materiales Avanzados, Chihuahua, Chihuahua, MAGNETS II Mexico (Poster Session) Ming Yue, Co-Chair GU-09. Magnetic properties of epitaxial Fe3O4 with various crystal Xubo Liu, Co-Chair orientations.T. Nagahama1, K. Tate1, Y. Matsuda1, N. Takahashi1 and T. Shimada11. Hokkaido University, Sapporo, Japan GV-01. Anomalous magnetic properties of single-phase MnBi grown from MnBi49 melt.X. Xiao1, P. Si 1, H. Feng1, Q. Ye2, S. Yu1 and GU-10. Potential application for spintronics of graphene/BN/Co 1 H. Ge 1. Zhejiang Key Lab of Magnetic Materials, China Jiliang systems. J. Hong1 1 and A. Hashmi 1. physics, Pukyong National University, Hangzhou, China; 2. Department of Physics, Univ, Busan, Republic of Korea Hangzhou Normal University, Hangzhou, China

GU-11. Influences of the first-to-second order magnetic phase GV-02. Effect of process parameters on the phase formation, particle transformation on electrical and magnetotransport properties 1,2 1 1 1 size and magnetic properties of MnBi nanoparticles prepared of La0.7Ca0.3-xBaxMnO3 T. Thanh , T. Lee , T. Phan , S. Yu and 1 1 3 by mechanochemical synthesis. V. Neelam , A. Gabay and 1. Department of Physics, Chungbuk National 1 D. Tuan G. Hadjipanayis 1. Department of Physics and Astronomy, University, Cheongju, Republic of Korea; 2. Institute of Materials University of Delaware, Newark, DE Science, Vietnam Academy of Science and Technology, Ha Noi, Viet Nam; 3. Department of Physics, University of Ulsan, Ulsan 680-749, Republic of Korea GV-03. Structure, phase transition, and magnetic properties of Co- doped MnBi alloys. M. Yue1, W. Geng1, D. Zhang1, Q. Lu1, Y. Liu1 and J. Zhang11. Beijing University of Technology, Beijing, GU-12. Observation of electron-electron interaction in magnetic China tunnel junctions with low resistance-area product. Y. Lee1, M. Tsunoda2, M. Takahashi2 and J. Wu11. Department of Physics, National Changhua University of Education, Changhua, Taiwan; GV-04. Structure and magnetic properties of LTP Mn-Bi nanosheets 2. Department of Electronic Engineering, Tohoku University, with ultra-high coercivity and significant anisotropy.R. Liu1, Sendai, Japan E. Niu1, M. Zhang1, Z. Li1, X. Zheng1, R. Wu1, W. Zuo1, B. Shen1, F. Hu1 and J. Sun11. State Key Laboratory for Magnetism, Institute of Physics,Chinese Academy of Sciences, Beijing, China 262 PROGRAM PROGRAM 263

GV-05. Structure and magnetic properties of bulk anisotropic GV-14. A study on the magnetic properties of melt spun Co-Hf-Zr-B MnBi/α-Fe nanocomposite permanent magnets with different nanocomposite ribbons.H.W. Chang1, Y.H. Lin2, C.W. Shih2 and α-Fe content.M. Yue1, D. Hu1, Y. Li1, D. Zhang1, W. Liu1, Q. Lu1, W.C. Chang21. Department of Applied Physics, Tunghai Y. Liu1 and J. Zhang11. Beijing University of Technology, Beijing, University, Taichung, Taiwan; 2. Department of Physics, National China Chung Cheng University,, Chia-Yi, Taiwan

GV-06. Preparation and magnetic properties of bulk MnBi/Co permanent magnets with high coercivity. Y. Ma 1, X. Liu1, V. Nguyen1, J. Yang2 and J. Liu11. Department of Physics, University of Texas at Arlington, Arlington, TX; 2. School of FRIDAY PLAZA BALLROOM A Physics, Peking University, Beijing, China MORNING 9:30 GV-07. High coercivity and temperature dependent magnetic properties of as-spun MnBi ribbons.K. Srikanti1, D. Prabhu1, Session GW G. Raghavan1, S. Maheshwar2 and K. Hono21. Centre for MAGNETIC RECORDING - MODELING Automotoive Energy Materials, ARCI, India, Chennai, Tamil Nadu, India; 2. Elements Strategy Initiative Center for Magnetic (Poster Session) Materials, National Institute for Materials Science, Tsukuba, Thomas Schrefl, Chair Ibaraki, Japan GW-01.Three-Dimensional Transition Characterization in ≤ ≤ Perpendicular and Shingled Recording. E.E. Lin1 and X. Wu11. GV-08. Hard magnetic properties of Mn2+xGa( 0 x 1) compounds.J. Wei1, C. Wang1, Y. Yang1, Y. Xia1, Z. Song1, Western Digital, Fremont, CA R. Wu1, Y. Yang1 and J. Yang11. School of Physics, Peking University, Beijing, China GW-02.An Iterative Inter-Track Interference Mitigation Technique for Two-Dimensional Magnetic Recording Systems. 1 1 1,2 3 GV-09. Hard Magnetic Properties Observed in Bulk Mn1-xGax. C. Warisarn , T. Losuwan , P. Supnithi and P. Kovintavewat 1. D. Brown1,2, K. Han2 and T.M. Siegrist3,41. Material Science & College of Data Storage Innovation, King Mongkut’s Institute of Engineering, Florida State University, Tallahassee, FL; 2. Magnet Technology Ladkrabang, Bangkok, Thailand; 2. Faculty of Science and Technology, National High Magnetic Field Engineering, King Mongkut’s Institute of Technology Ladkrabang, Laboratory, Tallahassee, FL; 3. Condensed Matter, National High Bangkok, Thailand; 3. Nakhon Pathom Rajabhat University, Magnetic Field Laboratory, Tallahassee, FL; 4. Department of Bangkok, Thailand Chemical and Biomedical Engineering, Florida State University, Tallahassee, FL GW-03.A kinetic Monte Carlo approach to modeling thermal decay in perpendicular recording media. T. Fal1, M.L. Plumer1, 1 1 1 2 GV-10. The phase evolution, magnetic and electric properties in J.P. Whitehead , J.I. Mercer , M.D. Leblanc , J. Ek and 1 1,2 1 K. Srinivasan21. Physics, Memorial University, St. John’s, NF, Mn60+xGa40-x (x=0-15) ribbons.J. Feng , X. Zhao , X. Ning , C. Shih2, W. Chang2, W. Liu1 and Z. Zhang11. Shenyang National Canada; 2. Western Digital, Longmont, CO Laboratory for Materials Science, Institute of Metal Research, Chinese academy of Sciences, Shenyang, China; 2. Department of GW-04.Study of Skew Angle Effects in a TDMR System. M. Elidrissi1, Physics, National Chung Cheng University, Chia-Yi, Taiwan K. Chan1, S.J. Greaves2, Y. Kanai3 and H. Muraoka21. Drive Systems and Technologies Division, Data Storage Institute, GV-11. Magnetocrystalline Anisotropy of Strained MnGa Alloys. Agency for Science, Technology And Research, Singapore, N. Al-Aqtash1 and R. Sabirianov11. Physics, University of Singapore; 2. RIEC, Tohoku University, Sendai, Miyagi, Japan; 3. Nebraska at Omaha, Omaha, NE Niigata Institute of Technology, Kashiwazaki, Niigata, Japan

GV-12. Effects of annealing temperature on phase structure and GW-05.Temperature dependence of MR ratio on dual spin valve 1 magnetic properties of Mn3Ga2 alloy. Q. Lu1, F. Yu1, M. Yue1, sensors. Y. Chen 1. National Tsing Hua University, Hsinchu, Y. Li 1, Y. Liu1 and J. Zhang11. College of Materials Science and Taiwan Engineering, Beijing University of Technology, Beijing, China GW-06.Influence of Writing and Reading ITI’s in terms of BAR in 1 1 GV-13. Effect of Co on the thermal stability and magnetic properties Shingled Magnetic Recording. H. Nobuhara , Y. Okamoto , 1 1 1 2 of AlNiCo 8 alloys. T. Liu1, W. Li1, M. Zhu1, Z. Guo1 and Y. Li11. M. Yamashita , Y. Nakamura , H. Osawa and H. Muraoka 1. Division of Functional Material, Central Iron & Steel Research Graduate School of Science and Engineering, Ehime University, Institute, Beijing, China Matsuyama, Japan; 2. The Research Institute of Electrical Communication, Tohoku University, Sendai, Japan 264 PROGRAM PROGRAM 265

GW-07.Jitter noise reduction by improving grain uniformity in 3:54 granular media. A. Hara1 and H. Muraoka11. RIEC, Tohoku University, Sendai, Miyagi, Japan HA-05. Electric-field induced ferromagnetic resonance in magnetic tunnel junctions. (Invited) T. Nozaki1,3, Y. Shiota2,3, S. Miwa2,3, F. Bonell2,3, H. Kubota1,3, K. Yakushiji1,3, S. Tamaru1, GW-08.Simulation study of effect of applied field angle and inter-dot R. Matsumoto1,3, M. Konoto1,3, T. Saruya1, H. Maehara1, spacing on switching field of 2 and 3 layer ECC dot array. A. Fukushima1,3, T. Shinjo1, S. Yuasa1,3 and Y. Suzuki2,31. N. Honda1 and K. Yamakawa21. Engineering, Tohoku Institute of Spintronics Research Center, National Institute of Advanced Technology, Sendai, Miyagi, Japan; 2. Akita Industrial Industrial Science and Technology, Tsukuba, Ibaraki, Japan; 2. Technology Center, Akita, Akita, Japan Graduate School of Engineering Science, Osaka University, Toyonaka, Osaka, Japan; 3. CREST, JST, Kawaguchi, Saitama, Japan

FRIDAY PLAZA BALLROOM BC AFTERNOON 1:30 FRIDAY PLAZA BALLROOM F AFTERNOON Session HA 1:30 SYMPOSIUM ON ELECTRIC FIELD CONTROL Session HB OF MAGNETIC PROPERTIES Christian Binek, Chair SPIN INJECTION INTO SEMICONDUCTORS Georg Schmidt, Chair

1:30 1:30 HA-01. Coupling Magnetism to Electricity in Multiferroic Heterostructures. (Invited) R. Ramesh11. Department of HB-01. Spin-pumping-induced spin transport in p-Si and graphene at 1 Materials Science and Engineering, University of California, room temperature. (Invited) M. Shiraishi 1. Osaka Univ., Berkeley, Berkeley, CA Toyonaka, Japan

2:06 2:06 HA-02. Voltage-Controlled Magnetic Tunnel Junctions. (Invited) HB-02. Quantitative Investigation of Spin-drift Velocity in Highly- 1 1 1 2 C. Chien11. Physics and Astronomy, Johns Hopkins University, doped n-type Si. M. Kameno , Y. Ando , T. Shinjo , H. Koike , 2 2 3 1 Baltimore, MD T. Sasaki , T. Oikawa , T. Suzuki and M. Shiraishi 1. Engineering Science, Osaka University, Toyonaka, Osaka, Japan; 2. SQ Research Center, TDK Corporation, Saku, Nagano, Japan; 2:42 3. AIT, Akita, Akita, Japan HA-03. Electric-Field Control of Magnetic Domain Wall Motion and Local Magnetization Dynamics in Ferromagnetic- 2:18 Ferroelectric Heterostructures. (Invited) S. van Dijken1, T. Lahtinen1, K. Franke1, A. Casiraghi1 and S. Hämäläinen11. HB-03. Spin Injection and Diffusion in Silicon Based Devices from a 1 1 1 Department of Applied Physics, Aalto University, Espoo, Finland Space Charge Layer. J. Ghosh , V. Sverdlov , T. Windbacher and S. Selberherr11. Institute for Microelectronics, Technical University of Vienna, Vienna, Austria 3:18

HA-04. Ferroelectric control of spin-dependent transport and 2:30 interface magnetism. (Invited) J.D. Burton11. Physics and Astronomy, University of Nebraska Lincoln, Lincoln, NE HB-04. Local magnetoresistance through Si at room temperature and its bias voltage dependence in ferromagnet/MgO/SOI lateral spin valves. Y. Saito1, M. Ishikawa1, T. Tanamoto1, T. Inokuchi1, H. Sugiyama1, K. Hamaya2 and N. Tezuka31. Corporate R&D Center, Toshiba Corporation, Kawasaki, Japan; 2. Department of Electronics, Kyushu University, Fukuoka, Japan; 3. Department of Materials Science, Tohoku University, Sendai, Japan 266 PROGRAM PROGRAM 267

2:42 4:18

HB-05. Spin Accumulation Induced in Ge using an Epitaxial Mn5Ge3 HB-11. Large room temperature magnetoresistance in organic spin 1 1 1 1 1 Schottky Contact.A.M. Spiesser , H. Saito , R. Jansen , valves based on La2/3Sr1/3MnO3 electrodes.B. Chen , Y. Zhou , S. Yuasa1 and K. Ando11. Spintronics Research Center, National S. Wang1, Y. Shi1, H. Ding1 and D. Wu11. Nanjing University, Institute of Advanced Industrial Science and Technology AIST, Nanjing, China Tsukuba, Ibaraki, Japan

2:54 HB-06. Surface Enhancement of Spin Injection in GaAs Detected with FRIDAY PLAZA BALLROOM E X-ray Magnetic Circular Dichroism. S. Zohar1, P.J. Ryan1, AFTERNOON 1 1 J. Kim and D.J. Keavney 1. Advanced Photon Source, Argonne 1:30 National Laboratory, Argonne, IL Session HC 3:06 MULTILAYERS II: EXCHANGE COUPLING HB-07. Direct Spin Injection into GaAs from Ferromagnetic Fe Si 3 AND SPIN-TRANSPORT Films. H. Hung1, T. Chiang2, B. Syu3, J.G. Lin4, S. Lee5, M. Hong6 and R. Kwo11. Department of Physics, National Tsing Randy Dumas, Chair Hua University, Hsinchu, Taiwan; 2. Department of Materials Science and Engineering, National Tsing Hua University, 1:30 Hsinchu, Taiwan; 3. Department of Physics, National Taiwan University, Taipei, Taiwan; 4. Center for Condensed Matter HC-01. Imaging magnetization reversal of interfacial exchange 1,2 2,3 1 Science, National Taiwan University, Taipei, Taiwan; 5. Institute coupling.(Invited) J. Camarero , E. Jiménez , P. Perna , 1 1,2 1,2 4 of Physics, Academic Sinica, Taipei, Taiwan; 6. Graduate Institute A. Bollero , J.F. Cuñado , D. Maccariello , J. Vogel , 1,2 3 5 5 of Applied Physics and Department of Physics, National Taiwan R. Miranda , F. Yakhou-Harris , G. Gaudin , B. Rodmacq , 5 5 5 5 University, Taipei, Taiwan E. Gautier , S. Auffret , B. Delaup and B. Dieny 1. IMDEA Nanoscience, Madrid, Spain; 2. Universidad Autonoma de Madrid and INC, Madrid, Spain; 3. ESRF, Grenoble, France; 4. 3:18 Institut Néel-CNRS, Grenoble, France; 5. SPINTEC, URA2512 HB-08. Absolute measurement of current spin polarization in CNRS/CEA,, Grenoble, France ferromagnet-semiconductor lateral spin valves.(Invited) C.C. Geppert1, S.J. Patel2, K.D. Christie1, C.J. Palmstrøm2 and 2:06 P.A. Crowell11. School of Physics and Astronomy, University of Minnesota, Minneapolis, MN; 2. Departments of Electrical and HC-02. Direct XMCD probing of the magnetization depth profile in 1 2 Computer Engineering and Materials, University of California, [Co/Pd]-CoFeB exchange springs. T. Nguyen , R. Knut , 1 1 1 2 3 Santa Barbara, CA V. Fallahi , S. Chung , S.M. Mohseni , O. Karis , R.K. Dumas , C. Miller4 and J. Åkerman1,31. Material Physics, Royal Institute of Technology (KTH), 16440 Kista, Sweden; 2. Department of 3:54 Physics and Astronomy, Uppsala University, Box 516, 75120, HB-09. Electrical Spin-Injection enhancement in III-V Spin-LEDs: Sweden; 3. Department of Physics, University of Gothenburg, Towards control of light polarization using spin-injected 41296, Sweden; 4. Department of Physics, University of South 1 2 3 2 Florida, 4202 East Fowler Avenue, Tampa, 33620, FL LASERs. J. Frougier , T. Zhang , S. Liang , P. Barate , P. Renucci2, X. Marie2, G. Baili4, M. Alouini4,5, I. Sagnes6, A. Garnache7, H. Jaffrès1, Y. Lu3 and J. George11. Unité mixte de 2:18 Physique CNRS-Thales, Palaiseau, France; 2. Laboratoire de Physique et Chimie de Nano-Objets, Toulouse, France; 3. Institut HC-03. Phase-transition via symmetry break in magnetic hybrid 1,3 1,3 2 Jean Lamour, Nancy, France; 4. Thales Research & Technology, structures. G. Hrkac , M.T. Bryan , T. Thomson , 4,5 2 Palaiseau, France; 5. Institut de Physique de Rennes, Rennes, L.J. Heyderman and G. Heldt 1. Engineering, Mathematics and France; 6. Laboratoire de Photonique et de Nanostructures, Physical Sciences, University of Exeter, Exeter, Devon, United Marcoussis, France; 7. Institut d’Electronique Fondamentale, Kingdom; 2. School of Computer Science, University of Montpellier, France Manchester, Manchester, United Kingdom; 3. Materials Science, University of Sheffield, Sheffield, United Kingdom; 4. Laboratory for Micro- and Nanotechnology, Paul Scherrer Institut, Villigen, 4:06 Switzerland; 5. Laboratory for Mesoscopic Systems, Department HB-10. Spin-dependent transport properties of strained InGaAs of Materials, ETH, Zuerich, Switzerland channel investigated through all electrical spin injection and detection. T. Akiho1, M. Yamamoto1 and T. Uemura11. Hokkaido University, Sapporo, Hokkaido, Japan 268 PROGRAM PROGRAM 269

2:30 3:42

HC-04. Variation of magnetization tilt angle in L11 CoPt-NiFe HC-10. Room temperature spin injection in organic semiconductors. 1 2,1 1 1 exchange springs against deposition temperature of L11 CoPt M. Galbiati , S. Tatay Aguilar , R. Mattana , P. Seneor , fixed layer. J. Hsu1, P. Saravanan1,2, C.L. Tsai1 and C.Y. Tsai31. K. Bouzehouane1, C. Deranlot1, A. Fert1 and F. Petroff11. Unité Physics, National Taiwan University, Taipei, Taiwan; 2. Defence Mixte de Physique CNRS/Thales, Palaiseau Cedex, France; 2. Metallurgical Research Laboratory, Hyderabad, India; 3. Instituto de Ciencia Molecular, Valencia, Spain graduate Institute of Materials Sience & Engineering, National Taiwan University, Taipei, Taiwan 3:54

2:42 HC-11. Origin of the Anisotropic GMR in magnetic multilayers. P. Perna1, D. Maccariello1,2, C. Rodrigo2, J.F. Cuñado2, HC-05. Exchange coupling and magnetic anisotropy at Fe/FePt A. Bollero1, M. Muñoz3,4, J. Prieto4, J. Akerman4, M. Romera4, interfaces. R. Cuadrado1, C.J. Aas1, P. Hasnip1, E. Plotnikova1, V. Cros5, J. Camarero1,2 and R. Miranda1,21. IMDEA L. Szunyogh2,3, L. Uzvardi2,3 and R.W. Chantrell11. Physics, The NANOSCIENCE, Madrid, Spain; 2. D.F.M.C., Universitad University of York, York, Yorkshire, United Kingdom; 2. Autonoma de Madrid, Madrid, Spain; 3. IMM (CNM-CSIC), Theoretical Physics, Budapest University of Technology, Madrid, Spain; 4. ISOM, Universidad Politecnica de Madrid, Budapest, Hungary; 3. Condensed Matter Research Group of Madrid, Spain; 5. CNRS/Thales and Universite Paris Sud 11, Hungarian Academy of Sciences, Budapest University of Paris, France Technology and Economics, Budapest, Hungary 4:06 2:54 HC-12. Infared Remote Sensing of Giant Magnetoresistance: HC-06. Control of perpendicular magnetic anisotropy in Experimental Confirmation of a Strong Correlation Between Ta/CoFeB/MgO/Ta ultra-thin films by using He ion induced the Magnetorefractive Effect and Giant Magnetoresistance in interface intermixing. A. Lamperti1, I. Barisic2,3, K. Garcia2, the Far Infrared. C.S. Kelley1, S.M. Thompson1, D. Gilks1, L. Herrera-Diez2, T. Devolder2, N. Vernier2, A. Digiacomo5, S. Poon1, S. LeFrançois2, P. Dumas2 and J. Matthew11. B. Ocker4, M. Fanciulli5,1, R. Mantovan1 and D. Ravelosona21. Department of Physics, University of York, York, United Kingdom; Laboratorio MDM, IMM-CNR, Agrate Brianza, MB, Italy; 2. 2. SMIS Beamline, SOLEIL Synchrotron, Paris, France Institut d’Electronique Fondamentale, CNRS, UMR 8622, Orsay, France; 3. Université Paris-Sud, Orsay, France; 4. Singulus 4:18 Technology AG, Kahl am Main, Germany; 5. Dipartimento di Scienza dei materiali, Università di Milano Bicocca, Milano, Italy HC-13. Structural and magneto-transport properties of CPP-GMR pseudo spin-valves with (110) epitaxial layers of Co2Fe(Ge0.5Ga0.5) Heusler alloy. J. Chen2,1, S. Li1, 3:06 T. Furubayashi1, Y. Takahashi1 and K. Hono1,21. Magnetic HC-07. Investigation of in-situ annealing and Boron diffusion in Materials Unit, National Institute for Material Science, Tsukuba- perpendicular Ta–CoFeB–MgO–CoFeB–Ta magnetic tunnel City, Japan; 2. Materials Science, Tsukuba University, Tsukuba- junction using polarized neutron reflectometry. V. Lauter1, City, Japan H. Ambaye1, T. Zhu2, Y. Yang2, R.C. Yu2 and J.Q. Xiao31. Neutron Sciences Directorate, Oak Ridge National Laboratory, Oak Ridge, TN; 2. Institute of Physics and Beijing National Laboratory for Condensed Matter Physics, Chinese Academy of Sciences, Beijing, China; 3. Department of Physics and Astronomy, University of Delaware, Newark, DE

3:18 HC-08. Electronic structure study of Fe/MgO/Fe/Co multilayer stack by x-ray magnetic circular dichroism. S. Gautam1, J. Singh2, K. Asokan2 and K. Chae11. Advanced Analysis Center, Korea Institute of Science and Technology, Seoul, Seoul, Republic of Korea; 2. Material Science Division, Inter-University Accelerator Centre, New Delhi, India

3:30 HC-09. Temperature driven transition from Giant to Tunneling magneto-resistance in hybrid inorganic-organic Fe3O4/Alq3/Co Spin Valve. P. Dey1, R. Rawat1, S. Potdar1, R. Choudhary1 and A. Banerjee11. UGC-DAE CSR Indore, Indore, India 270 PROGRAM PROGRAM 271

FRIDAY PLAZA BALLROOM D 3:06 AFTERNOON HD-07. Development of anisotropic in-plane stress during the film 1:30 formation as an origin of high magnetic anisotropy in FeCoB films applicable to microwave devices. H. Hayashibara1, Session HD R. Yohena1 and S. Nakagawa11. physical Electronics, Tokyo MICROWAVE AND MILLEMETER WAVE Institute of Technology, Meguro-ku, Tokyo, Japan MATERIALS 3:18 Nian Sun, Chair HD-08. Effect of annealing on the magnetic properties of Fe–(Ni Zn )Fe O nanocomposites.A. Giri1, S. Karna1 and 1:30 0.5 0.5 2 4 C. Dennis21. Weapons and Materials Research Directorate, US HD-01. High frequency millimeter wave absorption and rotation in Army Research Laboratory, Aberdeen Proving Ground, MD; 2. rhodium substituted ε-iron oxide.(Invited) A. Namai1, Material Measurement Laboratory, National Institute of M. Yoshikiyo1, T. Yoshida2, T. Miyazaki2, M. Nakajima3, Standards and Technology, Gaithersburg, MD T. Suemoto3, H. Tokoro1 and S. Ohkoshi1,41. The University of Tokyo, Tokyo, Japan; 2. DOWA Electronics Materials Co., Ltd., 3:30 Okayama, Japan; 3. Institute of Institute for Solid State Physics, the Univ. of Tokyo, Chiba, Japan; 4. CREST, JST, Tokyo, Japan HD-09. Fast magnetic response in GHz-band for columnar-structured Fe nanoparticle assembly. T. Ogawa1, H. Kura2, R. Tate1, T. Oikawa3, K. Hata3 and M. Takahashi21. Department of 2:06 Electronic Engineering, Tohoku University, Sendai, Japan; 2. New HD-02. Millimeter Wave Ferromagnetic Resonance in Gallium- Industry Creation Hatchery Center, Tohoku University, Sendai, Substituted ε-Iron Oxide.L. Chao1, M.N. Afsar1 and Japan; 3. Samsung R&D Institute Japan Co. Ltd., Yokohama, S. Ohkoshi21. Tufts University, Medford, MA; 2. University of Japan Tokyo, Tokyo, Japan 3:42 2:18 HD-10. Self-assembled 1-3D Pb(ZrTi)O3-NiFe2O4 nanocomposite HD-03. Low Magnetic Loss Co Z Hexaferrite for GHz Antenna films with low FMR linewidth for nonreciprocal microwave 2 1 1 1 1 1 Applications. W. Lee1, Y. Hong1, J. Lee1, J. Park1 and N. Luhrs11. devices.H. Zhang , F. Bai , Y. Wang , D. Wen and H. Zhang 1. Electrical and Computer Engineering and MINT Center, The State Key Laboratory of Electronic Thin Films and Integrated University of Alabama, Tuscaloosa, AL Devices, University of Electronic Science and Technology of China, Chengdu, China

2:30 3:54 HD-04. Tailoring magnetic and microwave absorption properties of 4+ 2+ glass-coated soft ferromagnetic microwires for microwave HD-11. Effect of Ti /Co Co-substitution on the Structural and 1,2 energy sensing applications.J. Devkota1, P. Colosimo2, Magnetic Properties of Cobalt Ferrite. C.I. Nlebedim , 1 1 1,2 J. Wingo1, A. Chen2, H. Srikanth1 and M. Phan11. Department of K.W. Dennis , W.R. McCallum and D.C. Jiles 1. Ames Physics, University of South Florida, Tampa, FL; 2. Applied Laboratory, US Department of Energy, Iowa State University, Physics Laboratory, University of Washington, Seattle, WA AMES, IA; 2. Department of Electrical and Computer Engineering, Iowa State University, Ames, IA

2:42 4:06 HD-05. Evidence and interpretation of a low-frequency resonance in flake-shaped ferromagnetic particle composites. J. Neige1, HD-12. Characterization of grain boundary conductivity of spin- T. Lepetit1, N. Malléjac1, A. Adenot-Engelvin1, A. Thiaville2 and sprayed ferrite using scanning microwave 1 1 2 2 N. Vukadinovic31. CEA-DAM Le Ripault, Monts, France; 2. LPS, microscopy.J. Myers , Y. Zhuang , T. Watanabe , N. Matsushita 3 Univ. Paris-Sud, CNRS UMR 8502, Orsay, France; 3. Dassault and M. Yamaguchi 1. Electrical engineering, Wright state Aviation, Saint-Cloud, France university, Dayton, OH; 2. Materials and Structures Laboratory, Tokyo Institute of Technology, Yokohama, Japan; 3. Electrical Engineering, Tohoku University, Sendai, Japan 2:54 HD-06. Effect of Er doping on the structural and magnetic properties of cobalt ferrite. S. Pratapani1, V.M. Reddy1, J.V. Tanjore2,3 and D. Das11. School of Engineering Science and Technology, University of Hyderabad, Hyderabad, India; 2. Department of Mechanical and Materials Engineering, University of Nebraska, Lincoln, NE; 3. Carpenter technology Corporation, Reading, PA 272 PROGRAM PROGRAM 273

FRIDAY GOVERNOR’S SQ 14 2:42 AFTERNOON HE-07. Micromagnetics with Dzyaloshinskii-Moriya interaction in 1:30 nanostructures. S. Rohart1, J. Sampaio2, A. Thiaville1, V. Cros2, J. Miltat1 and A. Fert21. Laboratoire de Physique des Solides, Session HE Université Paris-Sud and CNRS, Orsay, France; 2. Unité Mixte NANOPARTICLES IN ARRAYS II de Physique, CNRS/Thales, Palaiseau, France Kathryn Krycka, Chair 2:54

1:30 HE-08. Demagnetization and final metastable state in an array of coupled magnetic dots.R.V. Verba1, V.S. Tiberkevich2, HE-01. Sombrero-shaped Fe3O4 nanoelements with both out-of-plane G.A. Melkov1 and A.N. Slavin21. Faculty of Radiophysics, Taras and in-plane magnetization components fabricated by nano- Shevchenko National University of Kyiv, Kyiv, Ukraine; 2. 1 1 1 imprint lithography. B. Kwon , W. Zhang and K.M. Krishnan 1. Department of Physics, Oakland University, Rochester, MI Materials Science and Engineering, University of Washington, Seattle, WA 3:06

1:42 HE-09. Synthesis of ultrahigh-density sub 10 nm Co nanowires arrays by the method of phase separation. Y. Tian1,2, P. Mukherjee1,2, HE-02. Strucrural and magnetic characterizations of magnetite Z. Xu1, T. Jayaraman1,2, J.E. Shield1,2 and T. Li11. Mechanical & 1 1 1 nanoparticle self assemblies. K. Chesnel , Y. Cai , M. Trevino , Materials Engineering, University of Nebraska - Lincoln, Lincoln, 2 2 R. Harrison and B. Olsen 1. Physics, BYU, Provo, UT; 2. NE; 2. Nebraska Center for Materials and Nanoscience, Chemistry, BYU, Provo, UT University of Nebraska - Lincoln, Lincoln, NE

1:54 3:18

HE-03. Assembled Bimagnetic Membrane with FePt and Fe3O4 HE-10. Magnetization reversal of Co nanowires and its correlation to 1 1 Nanocubes by Langmuir-Blodgett Method. M. Zhou , W. Li , their hcp crystal phase orientation. M. Vázquez1, 1 1 2 M. Zhu , D. Zhou and Y. Hou 1. Central Iron and Steel Research D.G. Trabada1, Y. Ivanov1, O. Chubykalo-Fesenko1 and Institute, Beijing, China; 2. Peking University, Beijing, China A. Chuvilin21. Instituto de Ciencia de Materiales de Madrid (CSIC), Madrid, Spain; 2. CIC nanoGUNE Consolider., San 2:06 Sebastian, Spain HE-04. Magnetic pillar arrays by nanoparticle self-assembly and pattern transfer. T. Wen1, R.A. Booth1, S. Piotrowski1 and 3:30 1 S.A. Majetich 1. Physics, Carnegie Mellon University, Pittsburgh, HE-11. Gradient binary-alloy nanowire and its magnetic properties. PA M. Zeng1, H. Yang1 and R. Yu11. Materials Science and Engineering School, Beihang University, Beijing, China 2:18 HE-05. Real time monitoring of magnetic nanoparticle self-assembly 3:42 1 2 on surfaces of magnetic recording media. L. Ye , B. Qi , HE-12. Electronic and magnetic properties of Ni clusters on the 1 2 2 1 T. Pearson , Y. Cordeau , T.O. Mefford and T.M. Crawford 1. graphene Moiré probed by XAS and XMCD techniques. Physics and Astronomy, University of South Carolina, Columbia, T. Tietze1, P. Leicht2, M. Sicot2, A. Zusan2, M. Fonin2, G. Schütz2 SC; 2. Materials Science and Engineering, Clemson University, and E. Goering21. Modern Magnetic Systems, Max-Planck- Clemson, SC Institute for Intelligent Systems, Stuttgart, Germany; 2. Universität Konstanz, Konstanz, Germany 2:30 HE-06. Quantitative Decoding of Interactions in Tunable Nanomagnet Arrays Using First Order Reversal Curves. D.A. Gilbert1, G.T. Zimanyi1, R.K. Dumas1, M. Winklhofer2, A. Gomez3, N. Eibagi1, J.L. Vicent3,4 and K. Liu11. Physics, University of California, Davis, CA; 2. Earth & Environmental Sciences, Ludwig-Maximilians-Universität München, München, Germany; 3. Fisica Materiales, Universidad Complutense, Madrid, Spain; 4. IMDEA-Nanociencia, Cantoblanco, Madrid, Spain 274 PROGRAM PROGRAM 275

FRIDAY GOVERNOR’S SQ 15 2:42 AFTERNOON HF-07. Equiatomic CoPt thin films with extremely high 1:30 coercivity.B. Varghese1, S. Piramanayagam1, Y. Yang1, S. Wong1, H. Tan1, W. Lee1 and I. Okamoto21. Data Storage Institute, Session HF Singapore, Singapore; 2. Western Digital, Singapore, Singapore GRANULAR MEDIA FOR RECORDING Yingguo Peng, Chair 2:54 HF-08. Effect of Si/NiFe seed layers on doubly layered Ru 1:30 intermediate layers in perpendicular magnetic recording tape media. H. Sakai1, G. Saemma1 and S. Nakagawa11. Department HF-01. Effect of granular MnPt:C seed-layer in growing FePt:C of Physical Electronics, Tokyo Institute of Technology, Tokyo, 1 2 1 granules. W. Wen , K. Chang and C. Lai 1. Materials Science Japan and Engineering, National Tsing Hua University, Taiwan, Hsin- chu, Taiwan; 2. Seagate Technology, Fremont, CA 3:06

1:42 HF-09. Successful fabrication of high Ku columnar CoPt-SiO2 granular film sputtered under high substrate temperature. HF-02. Structure and magnetic properties of graded (001) oriented K. Tham1, S. Hinata2,4, S. Saito2 and M. Takahashi31. R&D / FePt films prepared by magnetron sputtering and rapid Marketing Division, Tanaka Holdings, Chiyoda-ku, Tokyo, Japan; 1,2 1 1 thermal annealing. Y. Yu , T.A. George , L. Yue and 2. Electronic Engineering, Tohoku University, Sendai, Miyagi, 1 D.J. Sellmyer 1. University of Nebraska-Lincoln, Lincoln, NE; 2. Japan; 3. Tohoku University New Industry Creation Hatchery School of Materials Science and Engineering, Jilin University, Center, Sendai, Miyagi, Japan; 4. Engineering, JSPS Research Chanchun, Jilin, China Fellow, Sendai, Miyagi, Japan

1:54 3:18 HF-03. Quantitative analysis of grain-boundary thickness HF-10. Microstructure Evolution and Magnetic Properties of FeB/Pt distribution for estimating the effective magnetic exchange Multilayers and FeBPt Composite Films. H. Su1,2 and interaction in ultra-high-density perpendicular recording S. Gupta2,11. Center for Materials for Information Technology, 1 1 1 1 1 media. H. Zou , F.Q. Zhu , M.E. Schabes , Y. Ikeda , S. Florez The University of Alabama, Tuscaloosa, AL; 2. Department of 1 and B. Gurney 1. HGST, A Western Digital Company, San Jose, Metallurgical Materials Engineering, University of Alabama, CA Tuscaloosa, AL

2:06 3:30 HF-04. Time dependent coercivity of granular media in a time scale HF-11. Using resonant small angle x-ray scattering to explore the 1 from nanosecond to sub-millisecond regime. N. Kikuchi , evolution of perpendicular magnetic recording media design. 2 1 1 1 A. Hotta , K. Kadonosawa , M. Furuta , S. Okamoto , V.V. Mehta1, T. Wang2,3, Y. Ikeda1, H. Do1, K. Takano1, S. Florez1, 1 2,3 O. Kitakami and T. Shimatsu 1. Institute of Multidisciplinary B.D. Terris1, B. Wu3,4, C. Graves3,4, M. Shu3,4, R. Rick3,4, Research for Advanced Materials, Tohoku University, Sendai, A. Scherz3, J. Stoehr3,5 and O. Hellwig11. San Jose Research Japan; 2. Frontier Research Institute for Interdisciplinary Center, HGST, A Western Digital Company, San Jose, CA; 2. Science, Tohoku University, Sendai, Japan; 3. Research Institute Department of Materials Science and Engineering, Stanford of Electrical Communication, Tohoku University, Sendai, Japan University, Stanford, CA; 3. Stanford Institute for Materials & Energy Science (SIMES), SLAC National Accelerator Laboratory, 2:18 Menlo Park, CA; 4. Department of Applied Physics, Stanford University, Stanford, CA; 5. Linac Coherent Light Source, SLAC HF-05. Correlation between the atomically resolved structure and the National Accelerator Laboratory, Menlo Park, CA magnetic properties of highly textured granular L10-FePt-C films with near-Stoner-Wohlfarth behaviour.S. Wicht1,2, V. Neu1, L. Schultz1,2, D. Weller3, O. Mosendz3, G. Parker3, 3:42 3 1 S. Pisana and B. Rellinghaus 1. IFW Dresden, Dresden, HF-12. Anisotropy and stiffness of CoPtRu alloys. A. Zamani1, Germany; 2. Institut für Festkörperphysik, TU Dresden, Dresden, M. Aurora2, T. Mckinnon2, E. Montoya2, B. Heinrich2, Germany; 3. HGST - A Western Digital company, San Jose, CA O. Mryasov3, P. Jonsson1, D. Suess4 and E. Girt21. Department of Physics and Astronomy, Uppsala University, Uppsala, Sweden; 2. 2:30 Department of Physics, Simon Fraser University, Burnaby, BC, Canada; 3. Department of Physics, University of Alabama, HF-06. Demonstration of the Thermal Stability Advantage of Tuscaloosa, AL; 4. Institute of Solid State Physics, Vienna 1 Advanced Exchange Coupled Composite Media. S.H. Florez , University of Technology, Wien, Austria Y. Ikeda1, T. Hennen1, F. Zhu1, K. Takano1 and B.D. Terris11. HGST a Western Digital Company, San Jose, CA 276 PROGRAM PROGRAM 277

3:54 2:18 HF-13. Electrically conductive underlayer to grow FePt-C HG-05. Dynamically tunable electromagnetically induced perpendicular recording media on glass substrates. transparency Using Terahertz MEMS Metamaterials. X. He1, B. Varaprasad1, T.K. Yukiko1 and H. Kazuhiro11. Magnetic J. Wang1, J. Jiang1, G. Yang2, F. Meng2 and Q. Wu21. School of Materials Unit, NIMS, Tsukuba, Ibaraki, Japan Applied Sciences, Harbin University of Science and Technology, China, Harbin, China; 2. Dept. of Electronic & Communications Engineering, Harbin Institute of Technology, Harbin, China

2:30 FRIDAY GOVERNOR’S SQ 16 AFTERNOON HG-06. Signal Crossing in perpendicular Nanomagnetic Logic. 1 1 1 2 1:30 I. Eichwald , S. Breitkreutz , J. Kiermaier , G. Csaba , D. Schmitt-Landsiedel1 and M. Becherer11. Lehrstuhl für Technische Elektronik, Technische Universität München, Session HG München, Germany; 2. Center for Nano Science and Technology, MICRO-ELECTRO-MECHANICAL SYSTEMS University of Notre Dame, Notre Dame, IN (MEMS) Joseph Davies, Chair 2:42 HG-07. Misalignment-Free Signal Propagation with 45° Clocking 1:30 Field for Magnetic Quantum-dot Cellular Automata. Z. Li1 and K.M. Krishnan11. Materials Science and Engineering HG-01. Wireless and passive temperature indicator utilizing the large Department, University of Washington, Seattle, WA hysteresis of magnetic shape memory alloys.B. Bergmair1, J. Liu3, T. Huber1, O. Gutfleisch2 and D. Suess11. TU Vienna, Vienna, Austria; 2. Technische Universität Darmstadt, Darmstat, 2:54 Germany; 3. IFW, Dresden, Germany HG-08. Stochastic Bifurcation, Fractal and Chaos Control of Giant Magnetostrictive Film-Shape Memory Alloy Composite 1:42 Cantilever Plate subjected to In-plane Harmonic and Stochastic Excitation. Z. Zhu1,2, Q. Zhang1 and J. Xu1,21. HG-02. Bioinspired Hair Flow Sensor Fabricated by the Mechanics, Tianjin University, Tianjin, China; 2. Tianjin Key Incorporation of Iron Nanowires into PDMS Micropillars. Laboratory of Nonlinear Dynamics and Chaos Control, Tianjin, 1 2 1 1 A. Alfadhel , R. Hetaimish , B. Li and J. Kosel 1. Computer, China Electrical and Mathematical Sciences and Engineering Division (CEMSE), King Abdullah University of Science and Technology (KAUST), Thuwal, Saudi Arabia; 2. Electrical and Computer 3:06 Engineering Department, Effat University, Jeddah, Saudi Arabia HG-09. Electroplated L10 CoPt thick-film permanent magnets. O.D. Oniku1, P.V. Ryiz1 and D.P. Arnold11. Electrical and 1:54 Computer Engineering, University of Florida, Gainesville, FL HG-03. Novel magnet configurations for high performance actuation of electrodynamic MEMS microspeakers. G. Sassine1, 3:18 I. Shahosseini1, M. Woytasik1, E. Martincic1, J. Moulin1 and 1 HG-10. Rapid Production of Highly Coercive Sm-Co Thin Films by 1. Institut d’Electronique Fondamentale (IEF), UMR 1 1 E. Lefeuvre Triode Sputtering. O. Akdogan and N. Dempsey 1. Institut 8622 CNRS Université Paris Sud, Orsay, France Neel,CNRS-UJF, Grenoble, France

2:06 HG-04. Controlled Assembly and Actuation of Nanoelectromechanical System (NEMS) Devices Using Nanoparticles with Unique Magnetic Interactions. K. Kim2, F. Zhu3 and D. Fan1,21. Materials Science and Engieering, University of Texas at Austin, Austin, TX; 2. Mechanical Engineering, The University of Texas at Austin, Austin, TX; 3. HGST, San Jose, TX 278 PROGRAM PROGRAM 279

FRIDAY GOVERNOR’S SQ 12 2:42 AFTERNOON HH-05. Towards Wide Temperature Range Control of the Metal- 1:30 Insulator Transition in Correlated Oxides by Modifying Orbital Occupancy. A.X. Gray1, N. Aetukuri2, J. Jeong2, Session HH A.H. Reid1, R. Kukreja1, H. Ohldag3, C.A. Jenkins4, E. Arenholz4, 2 2 1 COMPLEX OXIDES (BULK) M. Samant , S. Parkin and H.A. Durr 1. Stanford Institute for Materials and Energy Science, SLAC National Accelerator Dominic Ryan, Chair Laboratory, Menlo Park, CA; 2. IBM Research Division, Almaden Research Center, San Jose, CA; 3. Stanford Synchrotron 1:30 Radiation Lightsource, SLAC National Accelerator Laboratory, Menlo Park, CA; 4. Advanced Light Source, Lawrence Berkeley HH-01. Magnetically driven Slater metal-insulator transition in National Laboratory, Berkeley, CA NaOsO3. (Invited) S. Calder1, V.O. Garlea1, D. McMorrow2, M. Lumsden1, J. Kim3, J. Lang3, Y. Shi5, K. Yamaura4 and A. Christianson11. Oak Ridge National Laboratory, Oak Ridge, 2:54 TN; 2. London Centre for Nanotechnology, University College HH-06. Theoretical study of exchange coupling constant and Neel London, London, United Kingdom; 3. Advanced Photon Source, 1 1 temperature in distorted Cr2O3 Y. Kota , H. Imamura and Argonne National Laboratory, Argonne, IL; 4. National Institute M. Sasaki21. Spintronics Research Center, National Institute of for Materials Science, Tsukuba, Japan; 5. Chinese Academy of Advanced Industrial Science and Technology, Tsukuba, Japan; 2. Sciences, Beijing, China Department of Applied Physics, Tohoku University, Sendai, Japan

2:06 3:06 HH-02. Magnetic, structural and Pr-O bond changes at the low HH-07. Multiferroicity and magnetoelectric coupling in Haldane spin- temperature transition in Pr based half-doped metallic chain system, Dy BaNiO E.V. Sampathkumaran1, K. Singh1, 1 1,2 2 5 cobaltites.J. Padilla-Pantoja , J. Herrero-Martín , J. Garcia- T. Basu1, S. Chowki2, N. Mohapatra2, K.K. Iyer1 and 1 3 3 3 4 Muñoz , N. Brookes , K. Kummer , O. Watson , C. Ritter and P.L. Paulose11. Tata Institute of Fundamental Research, Mumbai, 5 V. Skumryev 1. Institut de Ciència de Materials de Barcelona - India; 2. Indian Institute of Technology, Bhubaneshwar, India CSIC, Bellaterra, Catalunya, Spain; 2. ALBA Synchrotron Light Source, Cerdanyola del Vallès, Catalunya, Spain; 3. European Synchrotron Radiation Facility, Grenoble, France; 4. Institut 3:18 Laue-Langevin, Grenoble, France; 5. Institució Catalana de HH-08. Neutron diffraction studies and magnetism in Ti doped Recerca i Estudis Avançats (ICREA) and Universitat Autònoma de 1 2 nanocrystalline SrFeO3-δ system.S. Arunachalam , D. Peram Barcelona, Bellaterra, Catalunya, Spain and S. Sanyadanam11. School of Physics, University of Hyderabad, Hyderabad, Andhra Pradesh, India; 2. UGC-DAE 2:18 Consortium for Scientific Research, Mumbai, India HH-03. Investigation Of Structural, Dielectric And Magnetic 3:30 Characteristics Of Double Pervoskites Pr2NiMnO6 And 1 1 Nd2NiMnO6 R. Yadav and S. Elizabeth Saji 1. Physics HH-09. Magnetic Interactions in LaMn0.5Co0.5O3 single crystals. Department, Indian Institute of Science, Bangalore, Karnataka, K. Manna1, V.S. Bhadram2, S. Elizabeth1, C. Narayana2 and India P.S. Anil Kumar11. Department of Physics, Indian Institute of Science, Bangalore, Karnataka, India; 2. Chemistry and Physics 2:30 of Materials Unit, Jawaharlal Nehru Centre for Advanced Scientific Research, Bangalore, Karnataka, India HH-04. Interplay between intrinsic and stacking-fault magnetic domains in bi-layered manganites.S. Hossain1, H. Ohldag1, S. Sarkar1, M. Burkhardt1, Y. Chuang2, A. Young2, A. Scholl2, 3:42 3 4 4 1 1 D. Dessau , H. Zheng , J. Mitchell , H. Duerr and J. Stoehr 1. HH-10. Magnetism in non-magnetic oxide surface and transition SLAC National Accelerator Laboratory, Menlo Park, CA; 2. metal doped oxides – Role of oxygen vacancy defects. Lawrence Berkeley National Laboratory, Berkeley, CA; 3. C. Mitra1, C. Lin2, A. Posadas2 and A. Demkov21. Oak Ridge University of Colorado, Boulder, CO; 4. Argonne National National Laboratory, Oak Ridge, TN; 2. The University of Texas Laboratory, Argonne, IL at Austin, Austin, TX 280 PROGRAM

3:54 HH-11. Heat transport of R_2Ti_2O_7 (R = rare earth) single crystals. X. Sun1, C. Fan1, F. Zhang1, Q. Li1, Z. Zhao1 and X. Zhao21. National Laboratory for Physical Sciences at Microscale, University of Science and Technology of China, Hefei, China; 2. School of Physical Sciences, University of Science and Technology of China, Hefei, China PROGRAM 281

- A - Akdogan O. (FF-08) ...... 207 Akdogan O. (HG-10) ...... 277 Aas C.J. (CQ-03) ...... 109 Åkerman J. (AG-06) ...... 31 Aas C.J. (HC-05) ...... 268 Åkerman J. (CB-05) ...... 91 Ababei G. (CF-06) ...... 100 Åkerman J. (CB-07) ...... 92 Ababei G. (EE-11) ...... 170 Åkerman J. (CP-02) ...... 106 Abboud K.A. (FD-08) ...... 203 Åkerman J. (CU-09) ...... 118 Abe K. (BF-10) ...... 66 Åkerman J. (DA-01) ...... 124 Abe T. (GF-01) ...... 242 Åkerman J. (DC-02) ...... 128 Ablekim T. (CG-10) ...... 103 Åkerman J. (DU-08) ...... 154 Aboljadayel R.O. (ES-13) ...... 186 Åkerman J. (EH-02) ...... 176 Abreu Araujo F. (BG-04) ...... 68 Åkerman J. (EH-05) ...... 176 Abreu Araujo F. (GP-05) ...... 249 Åkerman J. (EH-10) ...... 177 Abu Jeib H. (AB-07) ...... 19 Åkerman J. (EH-11) ...... 177 Acharya R. (DT-13) ...... 153 Åkerman J. (EU-09) ...... 190 Ackland K. (GD-10) ...... 239 Åkerman J. (HC-02) ...... 267 Acremann Y. (FB-04) ...... 199 Akerman J. (HC-11) ...... 269 Adak S. (FD-07) ...... 203 Akiho T. (AX-01) ...... 52 Adam J. (AG-12) ...... 32 Akiho T. (HB-10) ...... 266 Adam J. (FU-10) ...... 225 Akimitsu J. (GD-11) ...... 239 Adam R. (EU-08) ...... 190 Akiya T. (GF-13) ...... 244 Adam R. (FB-05) ...... 199 Akiyama T. (DF-09) ...... 136 Adekunle A. (BU-12) ...... 84 Akmaldinov K. (CD-07) ...... 96 Adenot-Engelvin A. (HD-05) ...... 270 Akshatala R. (FR-05) ...... 218 Adeyeye A.O. (AC-02) ...... 20 Akushichi T. (AX-05) ...... 53 Adeyeye A.O. (AC-04) ...... 21 Al MaMari F. (CP-08) ...... 107 Adeyeye A.O. (AC-06) ...... 21 Al-Aqtash N. (GV-11) ...... 262 Adeyeye A.O. (AP-03) ...... 35 Al-Jarah U. (FB-10) ...... 200 Adeyeye A.O. (BU-10) ...... 84 Al-Mahdawi M. (EB-10) ...... 164 Adeyeye A.O. (BU-11) ...... 84 Alaan U.S. (AD-02) ...... 23 Adeyeye A.O. (EU-07) ...... 190 Alaan U.S. (BE-12) ...... 64 Adeyeye A.O. (GE-04) ...... 240 Alahgholipour Omrani A. (DS-01) . .149 Adeyeye A.O. (GP-12) ...... 250 Alam S. (BA-01) ...... 54 Adriano C. (CS-03) ...... 113 Alarcon J. (BU-15) ...... 85 Adriano C. (CS-04) ...... 113 Alaria J. (AB-06) ...... 19 Adriano C. (CS-05) ...... 114 Alayo W. (EP-12) ...... 180 Adriano C. (ED-01) ...... 167 Alba Venero D. (DD-05) ...... 131 Adur R. (BC-12) ...... 59 Alba-Venero D. (AG-07) ...... 31 Adur R. (CU-08) ...... 118 Albert M. (AC-13) ...... 22 Adur R. (GC-02) ...... 235 Albert M. (BX-06) ...... 89 Aeschlimann M. (EU-08) ...... 190 Albert M. (BX-09) ...... 89 Aeschlimann M. (FB-05) ...... 199 Albert M. (GP-04) ...... 249 Aeschlimann M. (GB-14) ...... 235 Albertini F. (BE-13) ...... 64 Aeschlimann M. (GD-01) ...... 237 Albertini F. (CF-08) ...... 100 Aetukuri N. (HH-05) ...... 279 Alebrand S. (GD-01) ...... 237 Afid R. (DB-03) ...... 126 Aleksandrov Y. (CU-07) ...... 118 Afremov L.L. (FR-16) ...... 219 Alexander S. K. (BR-04) ...... 77 Afsar M.N. (FG-08) ...... 209 Alexander S.V. (BW-06) ...... 88 Afsar M.N. (HD-02) ...... 270 Alfadhel A. (BH-05) ...... 71 Aggarwal S. (BA-01) ...... 54 Alfadhel A. (HG-02) ...... 276 Agnus G. (BB-04) ...... 55 Alff L. (AE-12) ...... 27 Agnus G. (FU-10) ...... 225 Alff L. (AF-09) ...... 28 Ago H. (DP-02) ...... 143 Alff L. (BD-04) ...... 60 Agostinho Moreira J. (FS-13) ...... 221 Ali M. (EC-09) ...... 166 Agramunt-Puig S. (FP-11) ...... 214 Ali N. (FQ-14) ...... 217 Agrawal P. (GC-10) ...... 236 Ali N. (GQ-10) ...... 253 Aguero O. (CQ-09) ...... 110 Ali S.S. (DV-02) ...... 156 Aguilar J.A. (BE-12) ...... 64 Aliouane N. (CQ-09) ...... 110 Aguirre Contreras W. (ER-10) . . . . .183 Allard L.F. (FV-06) ...... 227 Ahlberg M. (DG-02) ...... 138 Allende S. (BQ-08) ...... 76 Ahmad E. (AC-05) ...... 21 Allende S. (BW-08) ...... 88 Ahn S. (BB-15) ...... 57 Allende S. (GP-15) ...... 251 Ahn S. (GC-10) ...... 236 Allibe J. (AE-03) ...... 25 Ahn S. (GE-11) ...... 241 Allwood D.A. (BB-10) ...... 56 Aidala K.E. (AU-16) ...... 48 Almeida A. (FS-13) ...... 221 Aidala K.E. (BG-15) ...... 70 Alouini M. (HB-09) ...... 266 Aimon N. (AE-08)* ...... 26 Altbir D. (BQ-08) ...... 76 Aimon N. (EQ-09) ...... 181 Altbir D. (BW-08) ...... 88 Aimon N.M. (DE-09) ...... 134 Altbir D. (GP-15) ...... 251 Aït Atmane K. (AF-11) ...... 29 Altounian Z. (BV-12) ...... 87 Ajan A. (DT-13) ...... 153 Altounian Z. (CQ-01) ...... 109 Akdogan O. (AV-11) ...... 49 Altwein D. (DE-07) ...... 134 282 PROGRAM PROGRAM 283

Álvarez-Alonso P. (EF-15) ...... 173 Antropov V. (DF-12) ...... 137 Atxitia U. (EU-12) ...... 191 Baldo M.A. (BB-15) ...... 57 Álvarez-Alonso P. (GQ-07) ...... 252 Anupam .. (ET-16) ...... 189 Auffret S. (AS-14) ...... 43 Baldo M.A. (GE-11) ...... 241 Alzate J. (ES-06) ...... 185 Aoki M. (AS-10) ...... 43 Auffret S. (AU-08) ...... 47 Balema V.P. (EF-12) ...... 172 Amamou W. (BC-12) ...... 59 Aoki Y. (DQ-02) ...... 145 Auffret S. (BC-01) ...... 58 Balicas L. (GA-05) ...... 232 Amamou W. (CD-12) ...... 96 Apalkov D. (DC-08) ...... 129 Auffret S. (BH-02) ...... 70 Balk A.L. (GR-13) ...... 255 Amaral V.S. (FS-13) ...... 221 Apalkov D. (GC-09) ...... 236 Auffret S. (FC-07) ...... 201 Balogh M.P. (DF-06) ...... 136 Ambaye H. (BE-04) ...... 63 Apalkov D. (GT-11) ...... 258 Auffret S. (GE-12) ...... 242 Baltz V. (AE-03) ...... 25 Ambaye H. (BP-15) ...... 74 Appino C. (ER-15) ...... 184 Auffret S. (HC-01) ...... 267 Baltz V. (AU-13) ...... 48 Ambaye H. (HC-07) ...... 268 Aragón A. (FR-02) ...... 217 Augustyniak B. (AW-15) ...... 52 Baltz V. (CD-07) ...... 96 Amemiya K. (DT-07) ...... 152 Aragón F.H. (DW-05) ...... 158 Aurino M. (AS-14) ...... 43 Baltz V. (ET-04) ...... 187 Ammar S. (AD-01) ...... 23 Arai H. (CB-11) ...... 92 Aurora M. (HF-12) ...... 275 Baltz V. (FC-07) ...... 201 Ammar S. (CF-15) ...... 101 Arai H. (CU-05) ...... 118 Avdeev M. (CF-10) ...... 100 Balzuweit K. (FW-09) ...... 229 Ammar S. (ED-11) ...... 168 Arai H. (DC-06) ...... 129 Avery A.D. (DP-16) ...... 144 Bance S. (BF-01) ...... 65 An B. (DG-09) ...... 139 Arai H. (EH-13) ...... 178 Avila M.A. (ED-01) ...... 167 Bance S. (BX-08) ...... 89 An C. (DT-12) ...... 152 Arai K. (DU-02) ...... 153 Awano H. (AU-12) ...... 47 Bandaru P.R. (BT-06) ...... 82 An J. (AR-04) ...... 40 Arai S. (ER-07) ...... 183 Ayele K.M. (FX-03) ...... 230 Bandiera S. (AD-08) ...... 24 An S. (AV-14) ...... 50 Arakawa A. (ET-07) ...... 188 Azzerboni B. (AH-01) ...... 32 Bandiera S. (AS-14) ...... 43 An S. (BF-08) ...... 66 Arami H. (BH-13) ...... 72 Azzerboni B. (BG-08) ...... 69 Banerjee A. (HC-09) ...... 268 An Y. (ES-10) ...... 186 Arami H. (FH-08) ...... 211 Azzerboni B. (DH-02) ...... 140 Banerjee N. (BD-09) ...... 61 An Y. (FS-06) ...... 220 Araújo J.M. (EU-14) ...... 191 Banerjee S. (EU-10) ...... 191 An Y. (FS-10) ...... 220 Araujo J.P. (FS-13) ...... 221 - B - Banobre-Lopez M. (ED-11) ...... 168 Anane A. (BC-09) ...... 59 Arena D. (FC-04) ...... 201 Bao L. (GQ-06) ...... 252 Anane A. (DB-09) ...... 127 Arena D.A. (CU-09) ...... 118 Bach J. (EA-05) ...... 162 Baraduc C. (AS-08) ...... 42 Anane A. (DH-15) ...... 142 Arena D.A. (EA-03) ...... 162 Back C.H. (BG-06) ...... 68 Baraduc C. (BG-10) ...... 69 Anane A. (FU-14) ...... 225 Arena D.A. (FV-04) ...... 227 Back C.H. (GP-07) ...... 250 Baranov N. (FQ-05) ...... 215 Anbusathaiah V. (AE-11) ...... 27 Arenholz E. (AD-02) ...... 23 Backes D. (CB-12) ...... 92 Barate P. (HB-09) ...... 266 Anderson I.E. (GF-02) ...... 242 Arenholz E. (AD-05) ...... 23 Baczewski L. (ET-03) ...... 187 Barati M. (DW-10) ...... 159 Anderson I.E. (GF-03) ...... 242 Arenholz E. (AF-10) ...... 29 Bader S.D. (DU-12) ...... 155 Barbagallo M. (BD-05) ...... 60 Anderson N.R. (FG-10) ...... 209 Arenholz E. (BE-01) ...... 62 Bader S.D. (FP-13) ...... 214 Barber Z.H. (CE-08) ...... 98 Andersson G. (AF-07) ...... 28 Arenholz E. (BE-12) ...... 64 Badini Confalonieri G. (GE-03) . . . .240 Barbosa G.F. (EX-03) ...... 196 Andersson G. (DG-02) ...... 138 Arenholz E. (HH-05) ...... 279 Bae Y. (AG-05) ...... 30 Barbosa T. (BW-10) ...... 88 Ando K. (BA-05) ...... 55 Arenholz E.A. (EQ-10) ...... 182 Baek B. (BD-11) ...... 61 Barisic I. (BS-16) ...... 81 Ando K. (DC-03) ...... 128 Arief M. (FR-01) ...... 217 Baggio-Saitovitch E. (AP-09) ...... 36 Barisic I. (FU-10) ...... 225 Ando K. (HB-05) ...... 266 Arnache O. (GS-15) ...... 257 Baggio-Saitovitch E. (DR-02) . . . . .147 Barisic I. (HC-06) ...... 268 Ando S. (CH-07) ...... 105 Arnalds U.B. (GE-06) ...... 241 Baggio-Saitovitch E. (EP-12) ...... 180 Barisik I. (AG-12) ...... 32 Ando S. (GR-10) ...... 255 Arnold D.P. (CG-06) ...... 102 Baghaie Yazdi M. (BD-04) ...... 60 Barmak K. (DF-01) ...... 135 Ando Y. (AC-11) ...... 22 Arnold D.P. (GF-11) ...... 244 BaghaieYazdi M. (AE-12) ...... 27 Barmak K. (DF-06) ...... 136 Ando Y. (AP-06) ...... 35 Arnold D.P. (GP-13) ...... 250 Bah M. (FR-14) ...... 219 Barmak K. (DV-04) ...... 156 Ando Y. (AV-05) ...... 49 Arnold D.P. (HG-09) ...... 277 Bahadur D. (EW-04) ...... 194 Barman A. (AC-10) ...... 22 Ando Y. (CU-06) ...... 118 Arora M. (AG-08) ...... 31 Bahoura M. (DS-10) ...... 150 Barman A. (BU-02) ...... 83 Ando Y. (DP-02) ...... 143 Arora M. (AP-04) ...... 35 Bai D. (FT-03) ...... 222 Barman A. (BU-04) ...... 83 Ando Y. (EU-13) ...... 191 Arora M. (CC-08) ...... 94 Bai F. (AX-12) ...... 54 Barman A. (BU-11) ...... 84 Ando Y. (FB-11) ...... 200 Arora M. (CD-13) ...... 97 Bai F. (BR-11) ...... 78 Barman A. (CP-06) ...... 107 Ando Y. (FX-09) ...... 231 Arout C.J. (FR-05) ...... 218 Bai F. (BU-07) ...... 84 Barman A. (DH-10) ...... 141 Ando Y. (GB-13) ...... 234 Arras R. (CC-12) ...... 94 Bai F. (EP-06) ...... 179 Barman S. (BU-02) ...... 83 Ando Y. (GB-14) ...... 235 Arrayangkool A. (CT-09) ...... 116 Bai F. (HD-10) ...... 271 Barman S. (BU-11) ...... 84 Ando Y. (GH-07) ...... 247 Arunachalam S. (HH-08) ...... 279 Bai J. (BR-04) ...... 77 Barnes . (BD-05) ...... 60 Ando Y. (GU-02) ...... 259 Asada H. (FP-04) ...... 213 Bai J. (CV-07) ...... 120 Barnes C. (AU-11) ...... 47 Ando Y. (HB-02) ...... 265 Asano H. (FX-01) ...... 230 Bai J. (CV-14) ...... 121 Barraud C. (DC-11) ...... 129 Andre T. (BA-01) ...... 54 Asbahi M. (GE-13) ...... 242 Bai J. (DT-09) ...... 152 Barrera G. (CF-08) ...... 100 Andreas C. (DX-11) ...... 161 Asenjo A. (EA-01) ...... 161 Bai X. (FW-12) ...... 229 Barrera G. (GR-03) ...... 254 Andreev N.V. (FS-11) ...... 221 Asenjo A. (FC-09) ...... 201 Bailey W.E. (BC-01) ...... 58 Barsukov I. (CB-09) ...... 92 Andrei P. (BQ-06) ...... 75 Ashida A. (AE-05) ...... 26 Bailey W.E. (BC-10) ...... 59 Barsukov I. (CU-15) ...... 119 Andrew J.S. (CG-06) ...... 102 Ashida T. (AD-06) ...... 23 Bailey W.E. (DG-08) ...... 139 Barsukov I. (DG-01) ...... 138 Andrieu S. (DC-04) ...... 128 Ashida T. (CE-09) ...... 98 Bailey W.E. (DU-03) ...... 153 Barthélémy A. (AE-02) ...... 25 Andriushchenko P.D. (FR-16) . . . . .219 Ashizawa Y. (CT-02) ...... 115 Baili G. (HB-09) ...... 266 Barthélémy A. (AE-03) ...... 25 Andrus M. (FD-08) ...... 203 Asilturk M. (BH-12) ...... 72 Bailleul M. (CP-09) ...... 107 Bartolome F. (DE-01) ...... 133 Anferov A. (BW-10) ...... 88 Asmat-Uceda M. (GP-10) ...... 250 Bain J. (FE-08) ...... 205 Bartolome J. (DE-01) ...... 133 Anghinolfi L. (DD-01) ...... 130 Asmat-Uceda M.A. (AH-03) ...... 33 Bain J.A. (EG-01) ...... 173 Barton L.S. (GQ-04) ...... 252 Anh Nguyen T.N. (DA-01) ...... 124 Asmat-Uceda M.A. (BG-09) ...... 69 Bain J.A. (FE-11) ...... 205 Barua R. (ED-13) ...... 169 Anil Kumar P.S. (DD-07) ...... 131 Asokan K. (HC-08) ...... 268 Baker .J. (BD-05) ...... 60 Barua R. (EF-06) ...... 172 Anil Kumar P.S. (HH-09) ...... 279 Assaf B. (EX-09) ...... 197 Baker A. (AH-11) ...... 34 Basaran A. (AD-10) ...... 24 Anilkumar P. (DC-02) ...... 128 Assaf B.A. (AB-02) ...... 18 Baker A.A. (GP-16) ...... 251 Bashir A.K. (DQ-06) ...... 145 Annavarapu V. (CW-03) ...... 121 Assaf B.A. (GH-12) ...... 248 Balachandran P. (DQ-12) ...... 146 Bassett D. (DP-16) ...... 144 Antonakos C. (FC-03) ...... 201 Astefanoaei I. (EW-02) ...... 194 Balamurugan B. (BF-04) ...... 65 Basso V. (GQ-09) ...... 252 Antonio Zapien J. (EQ-12) ...... 182 Astudillo A. (GS-15) ...... 257 Balamurugan B. (FV-12) ...... 228 Basu A. (DR-07) ...... 148 Antonyshyn I. (BD-03) ...... 60 Atitoaie A. (AT-04) ...... 44 Balamurugan B. (GF-09) ...... 243 Basu T. (DS-04) ...... 149 Antos R. (AT-06) ...... 44 Attane J. (AU-10) ...... 47 Balan A. (DD-01) ...... 130 Basu T. (HH-07) ...... 279 Antos R. (AT-07) ...... 45 Attané J. (BB-07) ...... 56 Balasubramanian B. (DF-15) ...... 137 Bataev D.S. (BF-12) ...... 67 Antos R. (GQ-05) ...... 252 Attane J. (BP-14) ...... 74 Baldasseroni C. (FC-02) ...... 200 Bates J.R. (FC-09) ...... 201 Antropov V. (AF-04) ...... 28 Attane J. (BU-09) ...... 84 Baldasseroni C. (FC-03) ...... 201 Batista C.D. (BG-03) ...... 68 Antropov V. (BD-12) ...... 61 Attard M. (ER-03) ...... 183 Baldereschi A. (GH-04) ...... 247 Batista S. (DR-02) ...... 147 284 PROGRAM PROGRAM 285

Batley J.T. (EC-05) ...... 165 Berger A.J. (BC-12) ...... 59 Biswas A. (BE-02) ...... 62 Boschen M.L. (GC-12) ...... 237 Batlle X. (DE-01) ...... 133 Berger H. (DS-01) ...... 149 Biswas A. (EE-05) ...... 170 Bose S. (BE-01) ...... 62 Batlle X. (EA-02) ...... 162 Bergeret F. (BD-09) ...... 61 Biswas A. (EF-01) ...... 171 Bose S. (BE-04) ...... 63 Batra T. (EG-03) ...... 173 Bergmair B. (HG-01) ...... 276 Biswas A. (EQ-03) ...... 181 Bosu S. (AB-04) ...... 19 Battiato M. (FB-01) ...... 198 Bergman A. (CB-10) ...... 92 Bito Y. (GR-06) ...... 254 Bosu S. (BP-13) ...... 74 Bauer H.G. (GP-07) ...... 250 Bergqvist L. (CB-10) ...... 92 Bittar E.M. (CQ-09) ...... 110 Botello-Zubiate M. (BV-03) ...... 86 Bauer U. (GB-01) ...... 233 Bergsten J. (GH-10) ...... 248 Blamire M. (BD-09) ...... 61 Bottauscio O. (BX-03) ...... 89 Bauer U. (GC-10) ...... 236 Berkowitz A.E. (DF-04) ...... 136 Blamire M.G. (CE-08) ...... 98 Bottauscio O. (CG-15) ...... 104 Baumann S. (FD-01) ...... 202 Bernard R. (BC-09) ...... 59 Blanco J.A. (EF-15) ...... 173 Boudou T. (BH-01) ...... 70 Baylor M. (BH-07) ...... 71 Bernard R. (DH-15) ...... 142 Blanco J.M. (CG-09) ...... 103 Boulle O. (AU-08) ...... 47 Béa H. (AE-03) ...... 25 Bernardo M.S. (GS-12) ...... 257 Blanco J.M. (CG-11) ...... 103 Boulle O. (DB-05) ...... 126 Beach G. (BB-15) ...... 57 Bernert K. (CU-07) ...... 118 Blazquez J.S. (CG-12) ...... 103 Boulle O. (DB-07) ...... 126 Beach G. (GB-01) ...... 233 Bernhard C. (BD-13) ...... 62 Blázquez J.S. (EF-14) ...... 173 Boulle O. (DU-06) ...... 154 Beach G. (GE-11) ...... 241 Bernstein G.H. (BB-02) ...... 55 Blazquez J.S. (FR-06) ...... 218 Bouzehouane K. (DC-11) ...... 129 Beach G.S. (AC-07) ...... 21 Bernstein G.H. (FP-06) ...... 213 Block A. (GD-06) ...... 238 Bouzehouane K. (HC-10) ...... 269 Beach G.S. (BH-06) ...... 71 Bernstein G.H. (GE-10) ...... 241 Blythe H. (AX-09) ...... 53 Bowden G.J. (FB-10) ...... 200 Beach G.S. (GC-10) ...... 236 Berrero C.A. (DW-04) ...... 158 Blythe H.J. (GH-06) ...... 247 Bowden S. (CE-04) ...... 98 Beach R.S. (DC-08) ...... 129 Bersweiler M. (AD-04) ...... 23 Bobba F. (DU-13) ...... 155 Bowe S.R. (BB-05) ...... 56 Beach R.S. (GT-11) ...... 258 Bersweiler M. (AG-01) ...... 30 Bocklage L. (DB-02) ...... 125 Bowe S.R. (CF-04) ...... 99 Beacham R. (CC-03) ...... 93 Bersweiler M. (GB-15) ...... 235 Bocquel J. (GH-13) ...... 248 Bowe S.R. (GB-05) ...... 233 Beardsley R.P. (BB-05) ...... 56 Bertacco R. (BE-05) ...... 63 Body D. (FE-02) ...... 204 Bowen D. (EG-08) ...... 174 Beardsley R.P. (CF-04) ...... 99 Bertacco R. (CE-01) ...... 97 Boehnke A. (EB-04) ...... 163 Bowen D. (EG-09) ...... 174 Beardsley R.P. (GB-05) ...... 233 Bertacco R. (ED-03) ...... 167 Boekelheide Z. (FW-01) ...... 228 Bowen D. (GD-03) ...... 238 Becerra C.C. (CQ-14) ...... 110 Bertotti G. (DP-09) ...... 143 Bøggild P. (ET-17) ...... 189 Bowlan J. (DE-04) ...... 133 Becherer M. (BB-14) ...... 57 Bertran F. (DC-04) ...... 128 Bogy D. (FT-14) ...... 223 Bowman R.M. (AD-11) ...... 24 Becherer M. (BQ-12) ...... 76 Beschoten B. (GC-12) ...... 237 Bohn F. (DR-02) ...... 147 Bowman R.M. (DB-11) ...... 127 Becherer M. (HG-06) ...... 277 Betancourt Reyes J.I. (DV-05) . . . . .156 Böhnert T. (ES-14) ...... 186 Bowman R.M. (ET-13) ...... 188 Bedau D. (DP-15) ...... 144 Betancourt Reyes J.I. (FQ-02) . . . . .215 Bohra M. (CS-09) ...... 114 Bowman R.M. (EU-06) ...... 190 Bedoya-Pinto A. (BP-16) ...... 74 Betto D. (AH-09) ...... 34 Bolanos G. (GS-15) ...... 257 Bozhko D.A. (AC-08) ...... 21 Beg M. (AC-13) ...... 22 Beyer M. (BD-13) ...... 62 Bollero A. (HC-01) ...... 267 Brächer T. (AC-11) ...... 22 Beg M. (BX-09) ...... 89 Beyersdorff B. (DG-07) ...... 139 Bollero A. (HC-11) ...... 269 Brächer T. (EC-11) ...... 166 Beg M. (GP-04) ...... 249 Beyersdorff B. (EA-05) ...... 162 Bonell F. (DC-04) ...... 128 Brady M.P. (FV-10) ...... 227 Beguhn S. (FG-06) ...... 209 Bhadram V.S. (HH-09) ...... 279 Bonell F. (GB-02) ...... 233 Braganca P.M. (EH-01) ...... 175 Beguivin A. (GB-10) ...... 234 Bhanja S. (GT-12) ...... 259 Bonell F. (HA-05) ...... 265 Braganca P.M. (GE-09) ...... 241 Behera B.C. (CW-03) ...... 121 Bhat S.V. (AQ-08) ...... 38 Bonetti S. (DA-01) ...... 124 Bramwell S. (GA-01) ...... 232 Beigne C. (AU-10) ...... 47 Bhat V. (AQ-04) ...... 38 Bonfim M. (AU-08) ...... 47 Brandão J. (AU-03) ...... 46 Beigné C. (AW-05) ...... 51 Bhat V. (DD-06) ...... 131 Bonfim M. (AU-14) ...... 48 Breitkreutz S. (BB-14) ...... 57 Beigné C. (BB-07) ...... 56 Bhat V.. (BC-04) ...... 58 Bonnetti S. (DU-01) ...... 153 Breitkreutz S. (BQ-12) ...... 76 Beigne C. (BU-09) ...... 84 Bhatia C. (BT-12) ...... 82 Bono D.C. (BH-06) ...... 71 Breitkreutz S. (HG-06) ...... 277 Belanovskiy A. (GP-05) ...... 249 Bhatia C.S. (CT-15) ...... 116 Bono D.C. (FU-11) ...... 225 Brenac A. (AW-05) ...... 51 Belashchenko K.D. (CE-07) ...... 98 Bhowmik D. (DH-03) ...... 140 Bono D.C. (GC-10) ...... 236 Brewer M.S. (GE-06) ...... 241 Belashchenko K.D. (FX-04) ...... 230 Bi L. (AT-07) ...... 45 Bookman L. (CB-06) ...... 91 Briones J. (AR-10) ...... 40 Bellaiche L. (AE-02) ...... 25 Bi W. (GF-05) ...... 243 Bookman L. (CB-07) ...... 92 Brissoneau V. (BU-15) ...... 85 Belova L. (CU-14) ...... 119 Bibby D. (ER-03) ...... 183 Bookman L. (DA-02) ...... 124 Bromberg D. (BS-03) ...... 79 Beltran J.J. (DW-04) ...... 158 Bibès M. (AE-02) ...... 25 Bookman L. (GP-01) ...... 249 Bromberg D. (FU-12) ...... 225 Belyea D.D. (EF-13) ...... 173 Bibes M. (AE-03) ...... 25 Boone C.T. (BC-05) ...... 58 Brookes N. (HH-02) ...... 278 Ben Youssef J. (DH-15) ...... 142 Bibes M. (CE-05) ...... 98 Boone C.T. (BC-07) ...... 59 Brown D. (GV-09) ...... 262 Benakli M. (AH-13) ...... 34 Bick J. (BF-06) ...... 66 Booth R.A. (DR-05) ...... 148 Brown G. (ES-01) ...... 185 Benakli M. (FT-07) ...... 222 Bickel J.E. (AU-16) ...... 48 Booth R.A. (EE-07) ...... 170 Brown G. (ES-03) ...... 185 Bender P. (DE-03) ...... 133 Bickel J.E. (BG-15) ...... 70 Booth R.A. (HE-04) ...... 272 Brown G. (EU-05) ...... 190 Benitez Romero M. (BC-06) ...... 58 Biegler L.T. (FT-15) ...... 223 Borchers J. (AF-10) ...... 29 Brown S.L. (BA-02) ...... 54 Benitez Romero M. (CC-03) ...... 93 Biegler L.T. (FT-17) ...... 223 Borchers J. (BE-04) ...... 63 Brown S.L. (GC-06) ...... 236 Benitez Romero M. (FC-13) ...... 202 Biegler L.T. (FT-18) ...... 223 Borchers J.A. (CC-09) ...... 94 Browning N.D. (BE-12) ...... 64 Bennati C. (GQ-09) ...... 252 Biegler L.T. (FT-19) ...... 223 Borchers J.A. (FC-02) ...... 200 Brucas R. (CU-09) ...... 118 Bennett B.R. (BB-08) ...... 56 Bigot J. (FB-03) ...... 198 Bordeaux N. (DF-01) ...... 135 Brück E. (CF-12) ...... 101 Bennett L.H. (BF-05) ...... 65 Binek C. (GB-12) ...... 234 Bordeaux N. (DF-06) ...... 136 Bruck E. (EF-07) ...... 172 Bennett L.H. (BQ-01) ...... 75 Bingham N. (AQ-02) ...... 37 Bordeaux N. (DV-04) ...... 156 Bruck E. (FQ-12) ...... 216 Bennett L.H. (CF-13) ...... 101 Bingham N.S. (AR-12) ...... 41 Bordel C. (CC-13) ...... 94 Brueck E. (CF-11) ...... 100 Bennett L.H. (GQ-15) ...... 253 Bingham N.S. (EF-01) ...... 171 Bordel C. (FC-02) ...... 200 Bryan M.T. (BB-10) ...... 56 Bennett S. (AV-07) ...... 49 Bingolbali A. (BH-12) ...... 72 Bordel C. (FC-03) ...... 201 Bryan M.T. (FF-10) ...... 207 Bennett S. (CX-06) ...... 123 Bionta M. (FB-04) ...... 199 Bordonali L. (AQ-10) ...... 38 Bryan M.T. (HC-03) ...... 267 Bennett S. (CX-09) ...... 123 Birringer R. (BF-06) ...... 66 Borisov K. (AB-06) ...... 19 Bryant N. (BV-02) ...... 85 Bennett S. (ER-12) ...... 184 Birringer R. (DE-03) ...... 133 Bornhoft J. (GF-12) ...... 244 Brydson R. (AB-01) ...... 18 Bennett S. (EX-09) ...... 197 Bisero D. (CF-03) ...... 99 Borrego J.M. (CG-12) ...... 103 Brydson R.M. (AG-07) ...... 31 Benoît C. (BH-02) ...... 70 Bisig A. (BG-02) ...... 68 Borsa F. (AQ-10) ...... 38 Buchanan K.S. (AH-03) ...... 33 Bentham C. (DD-09) ...... 132 Bisig A. (CT-15) ...... 116 Bortolotti P. (CB-01) ...... 91 Buchanan K.S. (BG-09) ...... 69 Benz S.P. (BD-11) ...... 61 Bisig A. (DB-13) ...... 127 Bortolotti P. (DA-03) ...... 125 Buchanan K.S. (EA-03) ...... 162 Bera A.K. (DD-07) ...... 131 Biskup N. (EA-02) ...... 162 Bortolotti P. (DB-09) ...... 127 Buchanan K.S. (FP-11) ...... 214 Beran L. (AT-06) ...... 44 Bisotti M. (AC-13) ...... 22 Bortolotti P. (EH-12) ...... 177 Buchanan K.S. (GP-10) ...... 250 Beran L. (GQ-05) ...... 252 Bisotti M. (BX-09) ...... 89 Borys P. (CB-02) ...... 91 Buchepalli V. (AQ-07) ...... 38 Berger A. (DE-07) ...... 134 Bisotti M. (GP-04) ...... 249 Bosch-Santos B. (DQ-01) ...... 145 Buchmeier M. (AG-13) ...... 32 Berger A. (GC-02) ...... 235 Biswas A. (AR-12) ...... 41 Bosch-Santos B. (DQ-07) ...... 145 Buda-Prejbeanu L. (AU-08) ...... 47 286 PROGRAM PROGRAM 287

Buda-Prejbeanu L.D. (DB-05) . . . . .126 Canizo-Cabrera A. (AP-07) ...... 36 Cavil S.A. (BB-05) ...... 56 Chang W.C. (BR-02) ...... 77 Buda-Prejbeanu L.D. (EH-15) . . . . .178 Cantoni M. (CE-01) ...... 97 Cavill S.A. (CF-04) ...... 99 Chang W.C. (EP-11) ...... 179 Buddhiraju M.S. (FR-05) ...... 218 Cantoni M. (ED-03) ...... 167 Cavoit C. (AS-08) ...... 42 Chang W.C. (GV-14) ...... 263 Budeanu L. (CF-06) ...... 100 Cao D. (BR-07) ...... 77 Cazayous M. (AE-02) ...... 25 Chang Y. (AP-07) ...... 36 Budhani R.C. (ET-05) ...... 188 Cao G.H. (CS-06) ...... 114 Cazayous M. (AE-09) ...... 26 Chang Y. (BS-05) ...... 79 Budhani R.C. (ET-16) ...... 189 Cao J. (AP-08) ...... 36 Celegato F. (CF-08) ...... 100 Chang Y. (BW-07) ...... 88 Buergler D. (ED-02) ...... 167 Cao J. (BR-04) ...... 77 Celegato F. (GR-03) ...... 254 Chang Y. (DV-01) ...... 156 Buford B. (AW-02) ...... 50 Cao J. (DT-09) ...... 152 Celik H. (FA-03) ...... 198 Chanthbouala A. (FU-14) ...... 225 Buford B. (GR-04) ...... 254 Cao L. (FF-06) ...... 207 Celinski Z. (AT-08) ...... 45 Chantrell R.W. (BX-07) ...... 89 Buhl M. (BG-01) ...... 67 Cao Q. (AW-13) ...... 52 Celinski Z. (CW-10) ...... 122 Chantrell R.W. (CQ-03) ...... 109 Buhot J. (AE-09) ...... 26 Cao R. (AH-10) ...... 34 Celinski Z. (CX-04) ...... 123 Chantrell R.W. (FB-09) ...... 200 Buhrman R.A. (DH-04) ...... 140 Cao Y. (CS-10) ...... 114 Celinski Z. (EQ-07) ...... 181 Chantrell R.W. (FE-05) ...... 205 Buhrman R.A. (FA-01) ...... 197 Capik M. (CG-01) ...... 101 Celinski Z. (ET-06) ...... 188 Chantrell R.W. (FF-09) ...... 207 Bukaemskiy A.A. (FR-12) ...... 218 Capobianchi A. (AF-06) ...... 28 Celinski Z. (FG-09) ...... 209 Chantrell R.W. (HC-05) ...... 268 Bunce C. (BG-01) ...... 67 Caprile A. (CC-06) ...... 93 Celinski Z. (FP-01) ...... 212 Chao L. (FG-08) ...... 209 Burgardt A. (ES-14) ...... 186 Caprile A. (CG-15) ...... 104 Celinski Z. (GD-02) ...... 238 Chao L. (HD-02) ...... 270 Burgess J.J. (BG-12) ...... 69 Carbonari A.W. (DQ-01) ...... 145 Celinski Z.J. (FG-11) ...... 210 Chao X. (CP-07) ...... 107 Burgy C. (BX-01) ...... 88 Carbonari A.W. (DQ-07) ...... 145 Cen Z. (BT-11) ...... 82 Chao X. (EU-15) ...... 191 Burgy C.D. (BQ-01) ...... 75 Cardelli E. (EG-12) ...... 175 Cen Z. (EE-08) ...... 170 Chao Y. (ES-05) ...... 185 Burkhardt M. (HH-04) ...... 278 Cardelli E. (ER-02) ...... 183 Cen Z. (FE-03) ...... 204 Chao Y. (FX-02) ...... 230 Burks E. (EP-14) ...... 180 Cardona-Serra S. (FD-02) ...... 202 Cerqueira C.F. (AX-07) ...... 53 Chao Z. (EV-15) ...... 193 Burnell G. (BC-06) ...... 58 Cardoso F. (AS-03) ...... 42 Cespedes O. (CP-08) ...... 107 Chappert C. (FU-08) ...... 225 Burnell G. (DD-02) ...... 130 Cardoso F. (CH-08) ...... 105 Cha E. (ER-05) ...... 183 Chappert C. (GT-14) ...... 259 Burnell G. (EC-05) ...... 165 Cardoso F.A. (BH-08) ...... 71 Cha H. (FW-05) ...... 228 Charilaou M. (CC-13) ...... 94 Burns L. (AV-08) ...... 49 Cardoso F.A. (CH-13) ...... 106 Chae K. (HC-08) ...... 268 Charlton T. (AB-01) ...... 18 Burrowes C. (FU-10) ...... 225 Cardoso S. (AS-03) ...... 42 Chai P. (GD-07) ...... 238 Charlton T. (AG-07) ...... 31 Burton J.D. (EB-11) ...... 164 Cardoso S. (AS-09) ...... 42 Chai Y. (DS-03) ...... 149 Chattopadhyay S. (DD-08) ...... 131 Burton J.D. (HA-04) ...... 264 Cardoso S. (BH-08) ...... 71 Chai Y. (GS-05) ...... 256 Chau K. (CR-07) ...... 112 Butler K.T. (FF-10) ...... 207 Cardoso S. (CH-03) ...... 104 Chajec W. (ER-13) ...... 184 Chau K. (CR-09) ...... 112 Butler W.H. (AB-12) ...... 20 Cardoso S. (CH-04) ...... 105 Chan K. (GW-04) ...... 263 Chau K. (CV-02) ...... 119 Butler W.H. (CD-10) ...... 96 Cardoso S. (CH-13) ...... 106 Chandra S. (AQ-09) ...... 38 Chau K. (CV-15) ...... 121 Büttner F. (BG-02) ...... 68 Carlotti G. (AC-02) ...... 20 Chandra S. (EE-05) ...... 170 Chau K.T. (CR-08) ...... 112 Buzzi M. (CF-09) ...... 100 Carlotti G. (AC-05) ...... 21 Chandra S. (EQ-03) ...... 181 Chaudhary S. (AB-08) ...... 19 Buzzi M. (FS-01) ...... 219 Carlotti G. (AH-02) ...... 33 Chandrasekaran S. (FT-03) ...... 222 Chaudhary S. (FX-06) ...... 230 Carlotti G. (CF-03) ...... 99 Chandrasekhar S. (ER-09) ...... 183 Chaudhary S. (GU-01) ...... 259 - C - Carman G. (CF-09) ...... 100 Chandrasekharan V. (ER-09) ...... 183 Chaves H.P. (DV-10) ...... 157 Carman G.P. (EF-08) ...... 172 Chaneac C. (CW-04) ...... 122 Chaves-OFlynn G.D. (AH-04) ...... 33 Caballero A.C. (GS-12) ...... 257 Carman G.P. (ES-06) ...... 185 Chang C. (AX-04) ...... 52 Che S. (EV-01) ...... 192 Cabrera-Pasca G.A. (DQ-07) ...... 145 Carman G.P. (GB-06) ...... 233 Chang C. (BP-06) ...... 73 Chebotkevich L. (BW-05) ...... 87 Cadogan J.M. (CS-06) ...... 114 Caron L. (CF-12) ...... 101 Chang C. (CG-13) ...... 103 Cheikhrouhou A. (CF-15) ...... 101 Cadogan J.M. (DQ-11) ...... 146 Caron L. (EF-07) ...... 172 Chang C. (DR-04) ...... 147 Chekanova L.A. (FR-12) ...... 218 Cadogan J.M. (EF-10) ...... 172 Carpenter E.E. (CW-06) ...... 122 Chang C. (DU-15) ...... 155 Chen A. (GE-07) ...... 241 Cagnon L. (DB-03) ...... 126 Carpenter E.E. (FR-03) ...... 217 Chang C. (ET-04) ...... 187 Chen A. (HD-04) ...... 270 Cagnon L. (FC-05) ...... 201 Carpenter E.E. (FR-09) ...... 218 Chang C. (EV-07) ...... 193 Chen B. (HB-11) ...... 267 Cai J. (DP-11) ...... 144 Carpenter E.E. (FV-04) ...... 227 Chang C. (FH-09) ...... 211 Chen C. (BH-01) ...... 70 Cai L. (EV-12) ...... 193 Carpenter R. (EP-13) ...... 180 Chang C.S. (CH-02) ...... 104 Chen C. (DC-12) ...... 130 Cai Y. (DE-05) ...... 134 Carpenter R. (FP-09) ...... 213 Chang H. (AV-08) ...... 49 Chen C. (EG-04) ...... 174 Cai Y. (HE-02) ...... 272 Carpentieri M. (DH-02) ...... 140 Chang H. (AV-13) ...... 50 Chen C. (EG-11) ...... 175 Calarco R. (ED-03) ...... 167 Carpentieri M. (DH-12) ...... 142 Chang H. (BC-02) ...... 58 Chen C. (EG-14) ...... 175 Calder S. (HH-01) ...... 278 Carreira S. (DE-02) ...... 133 Chang H. (BU-06) ...... 84 Chen C. (FR-11) ...... 218 Caldwell E. (CU-16) ...... 119 Carretero C. (AE-03) ...... 25 Chang H. (CX-12) ...... 124 Chen C. (FW-07) ...... 229 Calemczuk R. (BH-02) ...... 70 Carriço A.S. (DX-10) ...... 161 Chang H. (GC-01) ...... 235 Chen D. (AR-09) ...... 40 Calleja J.F. (BR-09) ...... 78 Carriço A.S. (EU-14) ...... 191 Chang H.W. (BR-02) ...... 77 Chen D. (CG-08) ...... 103 Calleja J.F. (FR-08) ...... 218 Carriço A.S. (EW-01) ...... 194 Chang H.W. (CS-09) ...... 114 Chen D. (CX-10) ...... 124 Calmels L. (CC-12) ...... 94 Carrière M. (FH-10) ...... 212 Chang H.W. (EP-11) ...... 179 Chen D. (EQ-07) ...... 181 Calmels L. (DC-04) ...... 128 Carroll K.J. (FV-03) ...... 226 Chang H.W. (FS-02) ...... 220 Chen D. (FG-11) ...... 210 Camarero J. (HC-01) ...... 267 Carroll K.J. (FV-04) ...... 227 Chang H.W. (GV-14) ...... 263 Chen E. (GE-10) ...... 241 Camarero J. (HC-11) ...... 269 Carter K.R. (FV-09) ...... 227 Chang J. (AB-13) ...... 20 Chen G. (EF-11) ...... 172 Camley R. (BH-10) ...... 72 Carva K. (FB-06) ...... 199 Chang J. (AX-02) ...... 52 Chen G. (FC-01) ...... 200 Camley R.E. (FG-09) ...... 209 Carvalho A.M. (FQ-01) ...... 215 Chang J. (CD-04) ...... 95 Chen G. (FC-12) ...... 202 Camley R.E. (FG-10) ...... 209 Casadei C.M. (AQ-10) ...... 38 Chang K. (DT-05) ...... 152 Chen H. (AS-06) ...... 42 Camley R.E. (FG-11) ...... 210 Casanova F. (BP-16) ...... 74 Chang K. (HF-01) ...... 274 Chen H. (BU-03) ...... 83 Camley R.E. (FP-01) ...... 212 Casiraghi A. (HA-03) ...... 264 Chang L. (AU-04) ...... 46 Chen H. (DH-08) ...... 141 Campanini M. (CF-08) ...... 100 Caslin K. (FD-11) ...... 204 Chang L. (DX-13) ...... 161 Chen H. (ES-15) ...... 186 Campbell S. (CF-10) ...... 100 Casoli F. (BE-13) ...... 64 Chang L. (GS-07) ...... 256 Chen H. (FP-03) ...... 213 Campbell S. (DD-13) ...... 132 Casoli F. (CF-08) ...... 100 Chang R. (BX-11) ...... 89 Chen H. (FT-16) ...... 223 Campbell S. (EF-02) ...... 171 Caspers C. (GH-01) ...... 246 Chang R. (DB-04) ...... 126 Chen H. (FU-02) ...... 224 Campbell S.J. (CQ-13) ...... 110 Cassignol C. (BF-01) ...... 65 Chang S. (AV-13) ...... 50 Chen J. (AP-13) ...... 36 Campbell S.J. (ED-10) ...... 168 Castillo A.M. (FE-13) ...... 206 Chang S. (DC-12) ...... 130 Chen J. (AW-07) ...... 51 Campbell S.J. (GQ-03) ...... 252 Castillo S. (GP-15) ...... 251 Chang W. (AV-13) ...... 50 Chen J. (BT-08) ...... 82 Campion R. (DP-07) ...... 143 Cavalcante F.H. (DQ-01) ...... 145 Chang W. (FQ-09) ...... 216 Chen J. (CD-12) ...... 96 Campion R.P. (BB-05) ...... 56 Cavalcante J.T. (DQ-01) ...... 145 Chang W. (GV-10) ...... 262 Chen J. (CS-07) ...... 114 288 PROGRAM PROGRAM 289

Chen J. (DQ-08) ...... 146 Cheng X. (DQ-12) ...... 146 Cho D. (AX-10) ...... 53 Chung S. (DA-01) ...... 124 Chen J. (ED-04) ...... 167 Cheng X. (EE-06) ...... 170 Cho H. (EW-06) ...... 195 Chung S. (DU-08) ...... 154 Chen J. (FQ-04) ...... 215 Cheng X.M. (AH-03) ...... 33 Cho K. (CX-03) ...... 123 Chung S. (EH-02) ...... 176 Chen J. (FQ-08) ...... 216 Cheng X.M. (GP-10) ...... 250 Cho M. (DG-09) ...... 139 Chung S. (HC-02) ...... 267 Chen J. (FU-13) ...... 225 Cheng Y. (FG-04) ...... 209 Cho S. (DR-10) ...... 148 Chureemart P. (BX-07) ...... 89 Chen J. (HC-13) ...... 269 Cheng Z. (CR-12) ...... 112 Cho S. (ES-11) ...... 186 Churyukanova M. (AR-08) ...... 40 Chen K. (AX-04) ...... 52 Cheng Z. (CS-08) ...... 114 Cho S. (GQ-12) ...... 253 Churyukanova M. (CG-09) ...... 103 Chen K. (EC-12) ...... 166 Cheng Z. (DW-09) ...... 159 Cho Y. (AX-10) ...... 53 Chuvilin A. (HE-10) ...... 273 Chen K. (EX-06) ...... 197 Cheong S. (AE-01) ...... 25 Cho Y. (AX-11) ...... 53 Cianci E. (BE-13) ...... 64 Chen L. (AT-03) ...... 44 Cheong S. (AE-07) ...... 26 Cho Y. (DU-11) ...... 155 Ciccarello T. (FF-06) ...... 207 Chen L. (ES-13) ...... 186 Cheong S. (AQ-02) ...... 37 Choe S. (AU-01) ...... 46 Cimpoesu D. (BQ-04) ...... 75 Chen L. (ET-01) ...... 187 Cheong S. (CE-02) ...... 97 Choe S. (AU-05) ...... 46 Cimpoesu D. (BU-12) ...... 84 Chen L. (EV-13) ...... 193 Cheong S.W. (AE-06) ...... 26 Choe S. (BU-05) ...... 83 Cimpoesu D. (CR-04) ...... 111 Chen L. (GQ-02) ...... 251 Chepulskyy R. (GC-09) ...... 236 Choe S. (DB-06) ...... 126 Cinchetti M. (CA-02) ...... 90 Chen M. (CV-15) ...... 121 Cherifi S. (CE-03) ...... 97 Choe S. (FU-09) ...... 225 Cinchetti M. (GB-14) ...... 235 Chen P. (DR-04) ...... 147 Cherifi S. (FC-10) ...... 202 Choe S. (FU-15) ...... 226 Cinchetti M. (GD-01) ...... 237 Chen P. (DT-08) ...... 152 Chern G. (BS-11) ...... 80 Choe S. (FU-16) ...... 226 Ciuta G. (AV-15) ...... 50 Chen P.J. (BS-06) ...... 79 Chern G. (DD-03) ...... 131 Choi G. (EG-06) ...... 174 Ciuta G. (FF-08) ...... 207 Chen R. (AV-06) ...... 49 Chern G. (ET-11) ...... 188 Choi G. (EG-10) ...... 174 Clarke D.J. (AH-03) ...... 33 Chen R. (EV-02) ...... 192 Chernenko V. (GQ-07) ...... 252 Choi H. (AE-08) ...... 26 Clarke D.J. (GP-10) ...... 250 Chen R. (EV-05) ...... 192 Chernova M.A. (FR-16) ...... 219 Choi H. (FW-03) ...... 228 Clarkson J. (EB-01) ...... 163 Chen R. (EV-10) ...... 193 Chernyashevsky O. (CB-08) ...... 92 Choi H. (FW-10) ...... 229 Claudio-Gonzalez D. (BG-14) ...... 70 Chen R. (EV-12) ...... 193 Chernychenko D. (GP-04) ...... 249 Choi J. (AR-13) ...... 41 Clausen P. (AC-08) ...... 21 Chen R. (GF-08) ...... 243 Chernyshenko D. (AC-13) ...... 22 Choi J. (CV-01) ...... 119 Coaquira J. (DW-05) ...... 158 Chen S. (AS-11) ...... 43 Chernyshenko D. (BX-06) ...... 89 Choi J. (CV-13) ...... 121 Coaquira J.H. (AQ-06) ...... 38 Chen S. (DV-01) ...... 156 Chernyshenko D. (BX-09) ...... 89 Choi J. (DF-02) ...... 135 Coelho A.A. (FQ-01) ...... 215 Chen S. (EB-08) ...... 164 Chernyshov A. (DT-13) ...... 153 Choi J. (ET-09) ...... 188 Coelho L.N. (CQ-09) ...... 110 Chen S. (GS-04) ...... 256 Chesnel K. (DE-05) ...... 134 Choi K. (AV-14) ...... 50 Coene A. (EW-12) ...... 195 Chen S.W. (BG-13) ...... 70 Chesnel K. (HE-02) ...... 272 Choi K. (AW-04) ...... 51 Coey J. (AB-06) ...... 19 Chen T. (DU-15) ...... 155 Chess J. (DW-04) ...... 158 Choi M. (AV-14) ...... 50 Coey J. (AH-09) ...... 34 Chen T.Y. (AB-05) ...... 19 Chess J. (EQ-11) ...... 182 Choi S. (CT-07) ...... 115 Coey J. (DH-01) ...... 140 Chen W. (BA-02) ...... 54 Cheung J. (EE-06) ...... 170 Choi S. (FR-11) ...... 218 Coey J. (ES-07) ...... 185 Chen W. (GC-06) ...... 236 Chi K.H. (BU-16) ...... 85 Choi W. (AB-13) ...... 20 Coey M. (GD-10) ...... 239 Chen X. (AF-12) ...... 29 Chia H.J. (BA-01) ...... 54 Choi Y. (AE-01) ...... 25 Coffee R. (FB-04) ...... 199 Chen X. (BV-11) ...... 86 Chiang D. (GS-07) ...... 256 Choi Y. (AE-07) ...... 26 Cohen R. (DW-05) ...... 158 Chen Y. (AP-15) ...... 37 Chiang T. (HB-07) ...... 266 Choi Y. (AX-10) ...... 53 Coisson M. (GR-03) ...... 254 Chen Y. (AR-14) ...... 41 Chiang M.Y. (CS-09) ...... 114 Choi Y. (CV-01) ...... 119 Collins-Mclntyre L.J. (GT-03) . . . . .258 Chen Y. (AT-10) ...... 45 Chiba D. (BB-11) ...... 57 Choi Y. (DW-06) ...... 158 Colosimo P. (HD-04) ...... 270 Chen Y. (AV-07) ...... 49 Chiba D. (EU-01) ...... 189 Choi Y. (FC-04) ...... 201 Colson D. (AE-09) ...... 26 Chen Y. (AV-08) ...... 49 Chiba D. (FU-07) ...... 224 Chopdekar R.V. (DD-01) ...... 130 Conde A. (CG-12) ...... 103 Chen Y. (CB-09) ...... 92 Chichay K. (FX-07) ...... 230 Chopdekar R.V. (FP-16) ...... 214 Conde A. (EF-14) ...... 173 Chen Y. (CU-15) ...... 119 Chichkov V.I. (FS-11) ...... 221 Chou H. (CS-09) ...... 114 Conde A. (FR-06) ...... 218 Chen Y. (CX-06) ...... 123 Chien C. (AG-09) ...... 31 Choudhary R. (HC-09) ...... 268 Constantinides S. (GF-02) ...... 242 Chen Y. (CX-09) ...... 123 Chien C. (AG-10) ...... 31 Chow G. (AP-13) ...... 36 Constantinides S. (GF-10) ...... 244 Chen Y. (DF-05) ...... 136 Chien C. (DP-11) ...... 144 Chow G. (BT-08) ...... 82 Contreras C. (FR-08) ...... 218 Chen Y. (DS-02) ...... 149 Chien C. (EC-07) ...... 166 Chow G. (ED-04) ...... 167 Contreras M. (BR-09) ...... 78 Chen Y. (DT-08) ...... 152 Chien C. (EC-10) ...... 166 Chowdhury A. (AP-10) ...... 36 Contreras M.F. (FH-03) ...... 211 Chen Y. (DT-12) ...... 152 Chien C. (HA-02) ...... 264 Chowki S. (HH-07) ...... 279 Coradin T. (CW-04) ...... 122 Chen Y. (EE-06) ...... 170 Chiesi V. (CF-08) ...... 100 Christianson A. (HH-01) ...... 278 Corbetta M. (DE-08) ...... 134 Chen Y. (ER-12) ...... 184 Chikoidze E. (FS-09) ...... 220 Christie K.D. (HB-08) ...... 266 Cordeau Y. (HE-05) ...... 272 Chen Y. (ET-12) ...... 188 Childress J.R. (EH-01) ...... 175 Chshiev M. (DP-12) ...... 144 Corodeanu S. (AR-07) ...... 40 Chen Y. (EX-09) ...... 197 Childress J.R. (GE-09) ...... 241 Chshiev M. (GB-07) ...... 234 Corodeanu S. (DG-04) ...... 138 Chen Y. (FA-03) ...... 198 Chinnasamy C. (EV-14) ...... 193 Chshiev M. (GD-09) ...... 239 Corona R.M. (DX-04) ...... 160 Chen Y. (FV-01) ...... 226 Chiorescu I. (FD-04) ...... 203 Chu J. (EB-01) ...... 163 Corona R.M. (GP-14) ...... 250 Chen Y. (FV-02) ...... 226 Chiou C. (BS-05) ...... 79 Chu Y. (EE-06) ...... 170 Coronado E. (FD-02) ...... 202 Chen Y. (FV-05) ...... 227 Chiriac H. (AR-05) ...... 40 Chuang L.C. (BR-02) ...... 77 Corrales J. (FR-08) ...... 218 Chen Y. (GW-05) ...... 263 Chiriac H. (AR-07) ...... 40 Chuang Y. (HH-04) ...... 278 Correia J.G. (FS-13) ...... 221 Chen Z. (CX-09) ...... 123 Chiriac H. (AR-15) ...... 41 Chubykalo-Fesenko O. (DG-03) . . .138 Correia M. (DE-02) ...... 133 Chen Z. (EX-05) ...... 196 Chiriac H. (CF-06) ...... 100 Chubykalo-Fesenko O. (EU-12) . . . .191 Corte H. (DX-06) ...... 160 Chen Z. (GG-04) ...... 245 Chiriac H. (DG-04) ...... 138 Chubykalo-Fesenko O. (HE-10) . . . .273 Corte- H. (FU-05) ...... 224 Chenchen J.W. (BS-14) ...... 81 Chiriac H. (EE-11) ...... 170 Chueh Y. (EE-06) ...... 170 Corte-Leon H. (GB-10) ...... 234 Cheng C. (BC-01) ...... 58 Chiriac H. (EW-02) ...... 194 Chumak A.V. (AC-08) ...... 21 Costa C.H. (AP-11) ...... 36 Cheng C. (BS-11) ...... 80 Chiu J. (DT-05) ...... 152 Chun S. (GS-05) ...... 256 Cottam M.G. (CU-04) ...... 117 Cheng C. (DG-08) ...... 139 Chiu S. (FS-05) ...... 220 Chunchu V. (CG-07) ...... 102 Cottam M.G. (EU-07) ...... 190 Cheng C. (DU-03) ...... 153 Chizhik N.A. (DV-03) ...... 156 Chung P. (FT-15) ...... 223 Couture S. (BQ-03) ...... 75 Cheng C. (ET-11) ...... 188 Chizhik N.A. (FR-12) ...... 218 Chung P. (FT-16) ...... 223 Cowburn R. (CC-01) ...... 93 Cheng D. (FG-04) ...... 209 Chmielewski M. (AW-15) ...... 52 Chung P. (FT-17) ...... 223 Cowburn R. (FU-10) ...... 225 Cheng L. (AX-09) ...... 53 Cho B. (BW-03) ...... 87 Chung P. (FT-18) ...... 223 Cowburn R.P. (BB-12) ...... 57 Cheng S. (CR-14) ...... 112 Cho B. (EP-01) ...... 178 Chung P. (FT-19) ...... 223 Cowburn R.P. (CC-02) ...... 93 Cheng S. (EG-04) ...... 174 Cho B. (FP-12) ...... 214 Chung S. (CB-05) ...... 91 Cowburn R.P. (CC-10) ...... 94 Cheng S. (EG-14) ...... 175 Cho C. (BU-05) ...... 83 Chung S. (CB-07) ...... 92 Cowburn R.P. (DB-12) ...... 127 Cheng T. (AX-03) ...... 52 Cho C. (FU-15) ...... 226 Chung S. (CP-02) ...... 106 Cowburn R.P. (ET-10) ...... 188 290 PROGRAM PROGRAM 291

Cowburn R.P. (GB-10) ...... 234 Daemen L. (FD-07) ...... 203 Dempsey N. (FF-08) ...... 207 Digiacomo A. (HC-06) ...... 268 Cox M. (EB-07) ...... 164 Dagotto E. (CS-12) ...... 115 Dempsey N. (HG-10) ...... 277 Dimian M. (BQ-06) ...... 75 Cox T. (GD-12) ...... 239 Dahal J.N. (CX-11) ...... 124 Dempsey N.M. (AF-08) ...... 28 Ding H. (AH-10) ...... 34 Crawford T.M. (HE-05) ...... 272 Dahliah D. (AB-07) ...... 19 Dempsey N.M. (AV-11) ...... 49 Ding H. (BP-03) ...... 73 Crespi V.H. (DD-03) ...... 131 Dai Y. (DX-09) ...... 161 Dempsey N.M. (AV-15) ...... 50 Ding H. (HB-11) ...... 267 Crevecoeur G. (ER-16) ...... 184 Daibou T. (CP-05) ...... 107 Dempsey N.M. (GF-11) ...... 244 Ding J. (AC-02) ...... 20 Crevecoeur G. (EW-12) ...... 195 Dalgliesh R. (CC-10) ...... 94 Demsar J. (BD-13) ...... 62 Ding J. (AC-06) ...... 21 Cros V. (BB-09) ...... 56 Danceanu C. (EE-11) ...... 170 Denardin J. (CW-04) ...... 122 Ding J. (AP-03) ...... 35 Cros V. (BC-09) ...... 59 Dang H. (AP-08) ...... 36 Denardin J.C. (AH-08) ...... 34 Ding J. (BU-11) ...... 84 Cros V. (BG-04) ...... 68 Dang H. (DT-09) ...... 152 Denardin J.C. (AR-10) ...... 40 Ding J. (BU-12) ...... 84 Cros V. (CB-01) ...... 91 Dankert A. (GH-10) ...... 248 Deng C. (CT-05) ...... 115 Ding J. (DR-14) ...... 149 Cros V. (DA-03) ...... 125 Dankert A. (GH-11) ...... 248 Deng D. (AG-09) ...... 31 Ding J. (EU-07) ...... 190 Cros V. (DB-07) ...... 126 Dannangoda C. (BH-11) ...... 72 Deng H. (GS-13) ...... 257 Ding J. (FW-08) ...... 229 Cros V. (DB-09) ...... 127 Dantas A.L. (DX-10) ...... 161 Deng L. (CX-12) ...... 124 Ding J. (GE-04) ...... 240 Cros V. (DH-15) ...... 142 Dantas A.L. (EU-14) ...... 191 Denisova E.A. (FR-10) ...... 218 Ding Q. (BT-06) ...... 82 Cros V. (EH-08) ...... 177 Dantas A.L. (EW-01) ...... 194 Denisova E.A. (FR-12) ...... 218 Ding Z. (DW-01) ...... 158 Cros V. (EH-09) ...... 177 Darques M. (DB-03) ...... 126 Dennis C. (FW-01) ...... 228 Dinulovic D. (DG-12) ...... 139 Cros V. (EH-12) ...... 177 Darsell J. (DF-02) ...... 135 Dennis C. (GE-07) ...... 241 Dionne G.F. (AT-07) ...... 45 Cros V. (FU-14) ...... 225 Das B. (DF-15) ...... 137 Dennis C. (HD-08) ...... 271 Dipanjan M. (BE-08) ...... 63 Cros V. (GP-05) ...... 249 Das D. (HD-06) ...... 270 Dennis C.L. (DE-03) ...... 133 Dirba I. (BF-07) ...... 66 Cros V. (HC-11) ...... 269 Das H. (AE-07) ...... 26 Dennis C.L. (EW-11) ...... 195 Dirckx J.J. (CR-13) ...... 112 Cros V. (HE-07) ...... 273 Dash S.P. (GH-10) ...... 248 Dennis K.W. (GF-03) ...... 242 Dirks A. (BF-07) ...... 66 Crowell P.A. (BP-15) ...... 74 Dash S.P. (GH-11) ...... 248 Dennis K.W. (HD-11) ...... 271 Divan R. (DR-06) ...... 148 Crowell P.A. (HB-08) ...... 266 Davies C. (AH-11) ...... 34 Deorani P. (DH-11) ...... 141 Divan R. (FG-12) ...... 210 Crowther L.J. (FH-12) ...... 212 Dawson F.P. (DR-12) ...... 148 Depeyrot J. (DV-10) ...... 157 Dix N. (BE-05) ...... 63 Crowther L.J. (GR-09) ...... 254 Dayal V. (CQ-15) ...... 110 Deranlot C. (AE-03) ...... 25 Dix N. (FC-10) ...... 202 Csaba G. (BB-02) ...... 55 de Groot C. (FU-03) ...... 224 Deranlot C. (DC-11) ...... 129 Djuhana D. (BU-14) ...... 85 Csaba G. (BB-14) ...... 57 de Groot P.A. (FB-10) ...... 200 Deranlot C. (DH-15) ...... 142 Dkhil B. (AE-02) ...... 25 Csaba G. (BQ-12) ...... 76 de Groot R.A. (EF-07) ...... 172 Deranlot C. (GP-05) ...... 249 Do B. (AU-12) ...... 47 Csaba G. (FP-06) ...... 213 de Heer W. (DE-04) ...... 133 Deranlot C. (HC-10) ...... 269 Do H. (HF-11) ...... 275 Csaba G. (GE-10) ...... 241 de Jong M. (BR-14) ...... 78 Derlet P.M. (DD-01) ...... 130 Doble M. (FR-05) ...... 218 Csaba G. (GT-07) ...... 258 de Jong S. (FB-04) ...... 199 Dery H. (BP-16) ...... 74 Döbrich F. (BF-06) ...... 66 Csaba G. (HG-06) ...... 277 de la Barrière O. (ER-15) ...... 184 Desai M. (DT-04) ...... 152 Dobrota C. (BQ-05) ...... 75 Cuadrado R. (FF-09) ...... 207 de la Figuera J. (FC-12) ...... 202 Desautels R. (EP-10) ...... 179 Dobrynin A. (AB-01) ...... 18 Cuadrado R. (HC-05) ...... 268 De la Presa P. (GU-08) ...... 260 Deshpande S. (BA-01) ...... 54 Dodge K. (DW-04) ...... 158 Cubukcu M. (BP-14) ...... 74 de la Venta J. (AD-10) ...... 24 Dessau D. (HH-04) ...... 278 Dogan N. (BH-12) ...... 72 Cuccoli A. (FD-03) ...... 203 De la Venta J. (CC-04) ...... 93 Devakul T. (GH-12) ...... 248 Doganay H. (FC-12) ...... 202 Cucolo A.M. (DU-13) ...... 155 De Long L. (AQ-04) ...... 38 Devkota J. (EW-03) ...... 194 Donahue M.J. (DX-03) ...... 160 Cuellar F.A. (BD-08) ...... 61 De Long L. (BC-04) ...... 58 Devkota J. (HD-04) ...... 270 Dong J. (EV-15) ...... 193 Cuello G.J. (EF-15) ...... 173 De Long L.E. (DD-06) ...... 131 Devolder T. (AG-12) ...... 32 Dong J. (EV-16) ...... 194 Cui B. (BV-01) ...... 85 de Loubens G. (BC-09) ...... 59 Devolder T. (FU-10) ...... 225 Dong J. (FR-07) ...... 218 Cui B. (DG-10) ...... 139 de Loubens G. (EH-08) ...... 177 Devolder T. (HC-06) ...... 268 Dong J. (FR-13) ...... 219 Cui B. (EV-14) ...... 193 de Loubens G. (EH-09) ...... 177 Dey P. (HC-09) ...... 268 Dong K. (BT-08) ...... 82 Cui B. (GQ-01) ...... 251 De Loubens G. (GP-05) ...... 249 Dhagat P. (AW-02) ...... 50 Dong S. (CQ-06) ...... 109 Cui C. (GS-01) ...... 255 de Medeiros S. (DR-02) ...... 147 Dhagat P. (AW-03) ...... 50 Dong S. (CS-12) ...... 115 Cui J. (AF-10) ...... 29 de Sousa M. (AP-09) ...... 36 Dhagat P. (GR-04) ...... 254 Dong S. (EQ-02) ...... 180 Cui J. (DF-02) ...... 135 De Teresa J.M. (BB-12) ...... 57 Dhar S.K. (DQ-02) ...... 145 Dong S. (GS-03) ...... 256 Cui J. (GB-06) ...... 233 De Vries M.A. (AG-07) ...... 31 Di Giorgio C. (DU-13) ...... 155 Dorneles L.S. (AH-08) ...... 34 Cui W. (BT-13) ...... 82 de Wit R. (FB-02) ...... 198 Di J. (EV-05) ...... 192 dos Reis R.D. (CQ-07) ...... 109 Cui X. (BG-07) ...... 69 Deac A. (CU-07) ...... 118 Di Sante D. (ED-03) ...... 167 Dou S. (CF-10) ...... 100 Cui Y. (ET-14) ...... 189 Deac A. (DA-01) ...... 124 Dianyu G. (DR-11) ...... 148 Dou S. (CQ-13) ...... 110 Cummings M. (AA-05) ...... 18 Debernardi A. (BE-13) ...... 64 Diao Z. (BG-12) ...... 69 Dou S. (DD-13) ...... 132 Cuñado J.F. (HC-01) ...... 267 Debernardi A. (GH-04) ...... 247 Dias Filho J.H. (FW-09) ...... 229 Dou S. (ED-10) ...... 168 Cuñado J.F. (HC-11) ...... 269 DeGeorge V. (BR-10) ...... 78 Dias T. (BH-08) ...... 71 Dou S. (EF-02) ...... 171 Currivan J. (BB-15) ...... 57 DeHerrera M. (BA-01) ...... 54 Diaz Michelena M. (GD-12) ...... 239 Dou S. (GQ-03) ...... 252 Currivan J. (GE-11) ...... 241 del Real R.P. (DG-03) ...... 138 Dieckhoff J. (BH-03) ...... 71 Dresselhaus P.D. (BD-11) ...... 61 Currivan J.A. (FU-11) ...... 225 del Val J.J. (CG-09) ...... 103 Dieny B. (AD-08) ...... 24 Drewello V. (EB-04) ...... 163 Cyrille M.C. (EH-15) ...... 178 del Val J.J. (FQ-11) ...... 216 Dieny B. (AE-03) ...... 25 Drögeler M. (GC-12) ...... 237 Czapkiewicz M. (AH-05) ...... 33 del Valle N. (FP-11) ...... 214 Diény B. (AS-08) ...... 42 Droubay T. (DF-02) ...... 135 Czerner M. (DC-13) ...... 130 Delaup B. (HC-01) ...... 267 Diény B. (BG-10) ...... 69 Drube W. (DC-02) ...... 128 Czerner M. (GU-07) ...... 260 Delenia E.A. (GC-06) ...... 236 Dieny B. (BH-02) ...... 70 Du A. (AQ-11) ...... 38 Czoschke P.J. (FT-06) ...... 222 Della Torre E. (BF-05) ...... 65 Dieny B. (CD-07) ...... 96 Du A. (EP-02) ...... 178 Della Torre E. (BQ-01) ...... 75 Dieny B. (CP-12) ...... 108 Du A. (EV-13) ...... 193 - D - Della Torre E. (BX-01) ...... 88 Dieny B. (DP-14) ...... 144 Du C. (BC-13) ...... 59 Della Torre E. (CF-13) ...... 101 Dieny B. (FC-07) ...... 201 Du C. (CU-08) ...... 118 d’Allivy Kelly O. (BC-09) ...... 59 Della Torre E. (GQ-15) ...... 253 Dieny B. (FH-10) ...... 212 Du C. (GC-02) ...... 235 d’Allivy Kelly O. (DH-15) ...... 142 Demidov V.E. (DA-04) ...... 125 Dieny B. (GB-07) ...... 234 Du H. (BR-07) ...... 77 da Silva J.H. (AX-08) ...... 53 Demiray A.S. (CU-06) ...... 118 Dieny B. (HC-01) ...... 267 Du H. (BR-08) ...... 78 Da-Col S. (DB-03) ...... 126 Demkov A. (HH-10) ...... 279 Dieterle G. (BG-06) ...... 68 Du H. (CS-07) ...... 114 Da-Col S. (FC-05) ...... 201 Demokritov S.O. (DA-04) ...... 125 Dietsch T. (BH-02) ...... 70 Du H. (DS-11) ...... 150 Dabade V. (FV-10) ...... 227 Dempsey N. (AS-08) ...... 42 Dietsch T. (FH-10) ...... 212 Du H. (FQ-15) ...... 217 Dabek M. (CH-04) ...... 105 Dempsey N. (EW-14) ...... 196 Dieudonné C. (EH-15) ...... 178 Du J. (AE-13) ...... 27 292 PROGRAM PROGRAM 293

Du J. (BV-07) ...... 86 Economou E. (EQ-07) ...... 181 Escobar M. (DB-04) ...... 126 Farle M. (DG-01) ...... 138 Du J. (ET-02) ...... 187 Economou E.C. (AT-08) ...... 45 Escobar M. (EH-14) ...... 178 Farmer B. (BC-04) ...... 58 Du M. (AF-12) ...... 29 Eddrief M. (CF-03) ...... 99 Escobar M.A. (BQ-03) ...... 75 Farmer B. (DD-06) ...... 131 Du W. (AP-16) ...... 37 Edelman I. (DW-07) ...... 159 Escobar R.A. (BQ-08) ...... 76 Farmer B.W. (AQ-04) ...... 38 Du Y. (AP-14) ...... 37 Edelman I. (ER-11) ...... 184 Escrig J. (AH-08) ...... 34 Fassbender J. (BG-01) ...... 67 Du Y. (AT-02) ...... 44 Edelstein A.S. (CH-10) ...... 105 Escrig J. (AR-10) ...... 40 Fassbender J. (CU-07) ...... 118 Du Y. (AT-03) ...... 44 Edmonds K.W. (BB-05) ...... 56 Escrig J. (BQ-13) ...... 76 Fassbender J. (ET-03) ...... 187 Du Y. (GQ-02) ...... 251 Egawa G. (FC-08) ...... 201 Escrig J. (DX-04) ...... 160 Faure-Vincent J. (BH-02) ...... 70 Duan Z. (DH-05) ...... 140 Egawa G. (FS-15) ...... 221 Escrig J. (GP-14) ...... 250 Fei X. (GQ-11) ...... 253 Duan Z. (EC-13) ...... 166 Eggebrecht T. (EB-04) ...... 163 Espejo A.P. (AR-10) ...... 40 Feiler L. (BP-07) ...... 73 Dubarry C. (BU-15) ...... 85 Eguchi G. (CS-01) ...... 113 Estrine E.C. (CF-05) ...... 99 Felser C. (AB-11) ...... 20 Dubenko I. (FQ-14) ...... 217 Eguchi T. (DG-05) ...... 138 Estrine E.C. (GQ-08) ...... 252 Felts A.C. (FD-08) ...... 203 Dubenko I. (GQ-10) ...... 253 Eibagi N. (CT-18) ...... 117 Etz C. (CB-10) ...... 92 Feng C. (EG-04) ...... 174 Ducruet C. (CD-07) ...... 96 Eibagi N. (GP-03) ...... 249 Evans R.F. (BX-07) ...... 89 Feng C. (EG-11) ...... 175 Duerr G. (BU-08) ...... 84 Eibagi N. (HE-06) ...... 272 Evans R.F. (CQ-03) ...... 109 Feng C. (EG-14) ...... 175 Duerr H. (DU-01) ...... 153 Eichwald I. (BB-14) ...... 57 Evans R.F. (FB-09) ...... 200 Feng E. (BR-07) ...... 77 Duerr H. (HH-04) ...... 278 Eichwald I. (BQ-12) ...... 76 Evans R.F. (FE-05) ...... 205 Feng G. (BS-06) ...... 79 Duh J. (DV-01) ...... 156 Eichwald I. (HG-06) ...... 277 Evans R.F. (FF-09) ...... 207 Feng H. (EV-13) ...... 193 Dulal P. (GD-06) ...... 238 Eid K. (AB-07) ...... 19 Evards E. (CH-10) ...... 105 Feng H. (GV-01) ...... 261 Dumas P. (BE-11) ...... 64 Eiji S. (BP-04) ...... 73 Evarts E. (EE-03) ...... 169 Feng J. (GV-10) ...... 262 Dumas P. (HC-12) ...... 269 Eimer S. (AG-12) ...... 32 Evarts E.R. (CP-10) ...... 107 Feng M. (AT-11) ...... 45 Dumas R.K. (AD-05) ...... 23 Eimer S. (BB-04) ...... 55 Evarts E.R. (DE-06) ...... 134 Feng M. (AT-12) ...... 45 Dumas R.K. (AG-06) ...... 31 Eimer S. (FU-10) ...... 225 Evarts E.R. (EW-15) ...... 196 Feng M. (CQ-04) ...... 109 Dumas R.K. (CB-07) ...... 92 Eisebitt S. (BG-02) ...... 68 Everschor-Sitte K. (XA-02) ...... 17 Feng M. (FS-14) ...... 221 Dumas R.K. (CU-09) ...... 118 Eisenbach M. (ED-07) ...... 168 Exl L. (BX-08) ...... 89 Feng Q. (GH-06) ...... 247 Dumas R.K. (DA-01) ...... 124 Eisenbach M. (EU-05) ...... 190 Feng Y. (DQ-15) ...... 147 Dumas R.K. (EH-05) ...... 176 Eixenberger J. (DW-04) ...... 158 - F - Feng Y. (GR-14) ...... 255 Dumas R.K. (HC-02) ...... 267 Eixenberger J. (EQ-11) ...... 182 Feng Z. (AH-10) ...... 34 Dumas R.K. (HE-06) ...... 272 Ek J. (GW-03) ...... 263 Faba A. (EG-12) ...... 175 Feng Z. (BP-03) ...... 73 Dumas-Bouchiat F. (EW-14) ...... 196 Eklund A. (CP-02) ...... 106 Faba A. (ER-02) ...... 183 Feng Z. (DS-12) ...... 150 Dumesnil K. (AD-04) ...... 23 Eklund A. (DA-01) ...... 124 Fabbrici S. (CF-08) ...... 100 Feng Z. (EX-05) ...... 196 Dumesnil K. (AG-01) ...... 30 El-Khatib S. (BE-04) ...... 63 Fabbris G. (ED-01) ...... 167 Fennie C.J. (AE-07) ...... 26 Dumesnil K. (BG-13) ...... 70 ElBidweihy H. (BQ-01) ...... 75 Fackler S. (AF-10) ...... 29 Ferchichi A. (BU-15) ...... 85 Dumesnil K. (GB-15) ...... 235 ElBidweihy H. (BX-01) ...... 88 Fackler S. (DF-14) ...... 137 Ferguson A. (DP-07) ...... 143 Dumitru I. (CR-04) ...... 111 ElBidweihy H. (CF-13) ...... 101 Fackler S.W. (CE-02) ...... 97 Fernandes R.M. (CS-05) ...... 114 Dumitru I. (EW-02) ...... 194 Elidrissi M. (GW-04) ...... 263 Fadahunsi L. (GP-04) ...... 249 Fernandez E. (GG-02) ...... 245 Dumont Y. (FS-09) ...... 220 Elizabeth S. (DD-07) ...... 131 Fadley C.S. (FC-02) ...... 200 Fernández J. (FC-12) ...... 202 Dung D. (GQ-12) ...... 253 Elizabeth S. (HH-09) ...... 279 Fadley C.S. (GE-06) ...... 241 Fernández J. (FR-02) ...... 217 Dung N.H. (EF-07) ...... 172 Elizabeth Saji S. (HH-03) ...... 278 Fainman S. (GD-01) ...... 237 Fernandez-Pacheco A. (BB-12) . . . . .57 Duong A. (ES-11) ...... 186 Elizalde Galindo J.T. (DV-05) . . . . .156 Fal T. (GW-03) ...... 263 Fernandez-Pacheco A. (CC-01) . . . . .93 Dupré L. (AH-07) ...... 33 Elizalde Galindo J.T. (FQ-02) ...... 215 Falcão E.H. (AX-07) ...... 53 Fernández-Pacheco A. (CC-02) . . . . .93 Dupré L. (AU-07) ...... 47 Elizalde Galindo J.T. (GU-08) . . . . .260 Faleev S. (AG-15) ...... 32 Fernandez-Pacheco A. (CC-10) . . . . .94 Dupré L. (EW-12) ...... 195 Ellis M.O. (BX-07) ...... 89 Fallahi V. (HC-02) ...... 267 Fernandez-Pacheco A. (ET-10) . . . . .188 Duque J.G. (DQ-13) ...... 146 Ellis M.O. (FB-09) ...... 200 Fan C. (AQ-13) ...... 39 Fernando P.R. (CQ-10) ...... 110 Duraj R. (ER-13) ...... 184 Ellison N.D. (DF-06) ...... 136 Fan C. (HH-11) ...... 280 Ferrara E. (CG-15) ...... 104 Durin G. (AH-07) ...... 33 Ellsworth D. (AG-10) ...... 31 Fan D. (HG-04) ...... 276 Ferré J. (AU-13) ...... 48 Durr H. (DU-05) ...... 154 Eloi J. (DE-02) ...... 133 Fan H. (FW-08) ...... 229 Ferreira Fo. A.F. (GG-11) ...... 246 Dürr H. (FB-04) ...... 199 Elyasi M. (BT-12) ...... 82 Fan P. (FT-10) ...... 222 Ferreira R. (AS-09) ...... 42 Durr H.A. (HH-05) ...... 279 Emori S. (GB-01) ...... 233 Fan R. (AD-12) ...... 24 Ferreira R. (CH-08) ...... 105 Dürrenfeld P. (EH-02) ...... 176 Emori S. (GC-10) ...... 236 Fan W.J. (BX-07) ...... 89 Ferreira R. (CH-12) ...... 106 Dürrenfeld P. (EU-09) ...... 190 Emoto A. (FP-04) ...... 213 Fan W.J. (FE-05) ...... 205 Ferreira R. (CH-13) ...... 106 Dussaux A. (DA-03) ...... 125 Enachescu C. (AT-04) ...... 44 Fan X. (CU-12) ...... 119 Fert A. (BB-09) ...... 56 Dussaux A. (EH-12) ...... 177 Enders A. (BQ-15) ...... 76 Fan X. (DX-05) ...... 160 Fert A. (BG-04) ...... 68 Dutra R. (BU-13) ...... 85 Endo Y. (DU-02) ...... 153 Fan X. (ES-15) ...... 186 Fert A. (DA-03) ...... 125 Dykes J. (FE-07) ...... 205 Endo Y. (FT-10) ...... 222 Fan X. (FA-03) ...... 198 Fert A. (DB-07) ...... 126 Endoh T. (BS-07) ...... 80 Fan Y. (CV-11) ...... 120 Fert A. (DC-11) ...... 129 - E - Endoh T. (CD-05) ...... 95 Fanciulli M. (FS-09) ...... 220 Fert A. (DH-15) ...... 142 Endoh T. (DC-01) ...... 128 Fanciulli M. (HC-06) ...... 268 Fert A. (EH-12) ...... 177 Eason K. (BC-03) ...... 58 Endoh T. (GT-10) ...... 258 Fang B. (EH-03) ...... 176 Fert A. (FU-14) ...... 225 Eason K. (EH-06) ...... 176 Enrico E. (GR-03) ...... 254 Fang C. (CG-14) ...... 104 Fert A. (GP-05) ...... 249 Ebels U. (BC-01) ...... 58 Epp S. (FB-04) ...... 199 Fang D. (DP-07) ...... 143 Fert A. (HC-10) ...... 269 Ebels U. (BU-15) ...... 85 Erbe A. (BG-01) ...... 67 Fang L. (AF-10) ...... 29 Fert A. (HE-07) ...... 273 Ebels U. (CP-12) ...... 108 Eremin E.V. (DV-03) ...... 156 Fang L. (DF-14) ...... 137 Fert A. (ZA-01) ...... 231 Ebels U. (EH-15) ...... 178 Eremin E.V. (FR-10) ...... 218 Fangohr H. (AC-13) ...... 22 Fetzer R. (GB-14) ...... 235 Ebina Y. (AX-01) ...... 52 Eremin I. (BW-10) ...... 88 Fangohr H. (BX-06) ...... 89 Fielicke A. (DE-04) ...... 133 Ebnabbasi K. (CR-16) ...... 113 Erickson M. (BP-15) ...... 74 Fangohr H. (BX-09) ...... 89 Figueira M. (DQ-05) ...... 145 Ebnabbasi K. (CX-07) ...... 123 Erickson M.J. (DD-03) ...... 131 Fangohr H. (GP-04) ...... 249 Figueiredo W. (DE-02) ...... 133 Ebnabbasi K. (CX-08) ...... 123 Eriksson O. (CB-10) ...... 92 Fani Sani F. (BG-12) ...... 69 Figueroa A.I. (DE-01) ...... 133 Ebnabbasi K. (GB-09) ...... 234 Eriksson O. (DE-04) ...... 133 Farge E. (EW-14) ...... 196 Figueroa-Garcia A. (AH-11) ...... 34 Echtenkamp W. (GB-12) ...... 234 Ermolinsky B. (BH-11) ...... 72 Farhan A. (DD-01)* ...... 130 Figueroa-Garcia A. (GP-16) ...... 251 Eckert J.C. (ES-08) ...... 186 Escobar M. (AH-12) ...... 34 Farias Mancilla J.R. (DV-05) ...... 156 Filatov E.Y. (DV-03) ...... 156 Eckert J.C. (ES-09) ...... 186 Escobar M. (BX-11) ...... 89 Farle M. (CU-07) ...... 118 Fin S. (CF-03) ...... 99 294 PROGRAM PROGRAM 295

Fina I. (CE-01) ...... 97 Frankowski M. (AH-05) ...... 33 Fukunaga H. (DV-07) ...... 157 Ganeshraj C. (CQ-02) ...... 109 Fina I. (EB-01) ...... 163 Franz C. (DC-13) ...... 130 Fukunaga H. (EV-08) ...... 193 Ganguly A. (BU-11) ...... 84 Finizio S. (CF-09) ...... 100 Franz C. (GU-07) ...... 260 Fukunaga H. (EV-09) ...... 193 Ganguly A. (CP-06) ...... 107 Finizio S. (FS-01) ...... 219 Franzitta V. (CV-05) ...... 120 Fukuoka M. (GG-06) ...... 245 Ganguly A. (DH-10) ...... 141 Finocchio G. (AH-01) ...... 32 Franzitta V. (GG-07) ...... 245 Fukushi T. (EW-10) ...... 195 Gangwar A. (BG-06) ...... 68 Finocchio G. (BG-08) ...... 69 Frauen A. (DE-07) ...... 134 Fukushima A. (BS-12) ...... 80 Gangwar A. (GP-07) ...... 250 Finocchio G. (BX-04) ...... 89 Frauen A. (ES-14) ...... 186 Fukushima A. (CB-01) ...... 91 Ganshina E. (FX-07) ...... 230 Finocchio G. (DH-02) ...... 140 Freeland J.W. (BD-08) ...... 61 Fukushima A. (CB-11) ...... 92 Gao J. (AT-02) ...... 44 Finocchio G. (DH-12) ...... 142 Freeman M.R. (BG-12) ...... 69 Fukushima A. (CP-01) ...... 106 Gao J. (AT-03) ...... 44 Fiorillo F. (CG-15) ...... 104 Freitas P. (AS-03) ...... 42 Fukushima A. (CU-05) ...... 118 Gao J. (BE-06) ...... 63 Fiorillo F. (ER-15) ...... 184 Freitas P. (CH-08) ...... 105 Fukushima A. (DA-03) ...... 125 Gao J. (EP-05) ...... 179 Fischbacher J. (BF-01) ...... 65 Freitas P.P. (AS-09) ...... 42 Fukushima A. (DC-03) ...... 128 Gao J. (GQ-02) ...... 251 Fischer J. (DE-08) ...... 134 Freitas P.P. (BH-08) ...... 71 Fukushima A. (DC-06) ...... 129 Gao T. (AF-10) ...... 29 Fischer P. (AC-12) ...... 22 Freitas P.P. (CH-03) ...... 104 Fukushima A. (EH-12) ...... 177 Gao T. (CE-02) ...... 97 Fischer P. (BG-11) ...... 69 Freitas P.P. (CH-04) ...... 105 Fukushima A. (EH-13) ...... 178 Gao T. (CE-04) ...... 98 Fischer P. (GE-05) ...... 240 Freitas P.P. (CH-12) ...... 106 Fukushima A. (FU-14) ...... 225 Gao T. (DF-14) ...... 137 Fischer P. (GP-03) ...... 249 Freitas P.P. (CH-13) ...... 106 Fukushima A. (GU-04) ...... 259 Gao X. (BR-08) ...... 78 Fischer P.J. (BB-10) ...... 56 Freitas R.S. (CQ-14) ...... 110 Fukushima A. (GU-13) ...... 261 Gao X. (DS-11) ...... 150 Fisher T. (BW-10) ...... 88 Freitas S. (CH-08) ...... 105 Fukushima A. (HA-05) ...... 265 Gao Y. (AX-09) ...... 53 Fisk Z. (CS-04) ...... 113 Friedlein J. (GB-08) ...... 234 Fukushima M. (DU-02) ...... 153 Gao Y. (CR-01) ...... 111 Fisk Z. (CS-05) ...... 114 Frielinghaus H. (BF-06) ...... 66 Fukuzaki T. (BF-10) ...... 66 Gao Y. (EG-02) ...... 173 Fitchorov T. (DS-02) ...... 149 Fries M. (EF-03) ...... 171 Fullerton E. (DB-04) ...... 126 Garbovskiy Y. (AT-08) ...... 45 Fitchorov T.I. (ER-12) ...... 184 Frincu B. (AF-09) ...... 28 Fullerton E.E. (BQ-03) ...... 75 García F.A. (DQ-13) ...... 146 Fitzsimmons M. (BE-02) ...... 62 Frincu B. (DF-07) ...... 136 Fullerton E.E. (CT-18) ...... 117 Garcia K. (AG-12) ...... 32 Fitzsimmons M. (BE-04) ...... 63 Frisch J. (DU-01) ...... 153 Fullerton E.E. (DC-07) ...... 129 Garcia K. (BB-04) ...... 55 Fitzsimmons M.R. (BD-08) ...... 61 Frisk A. (DG-02) ...... 138 Fullerton E.E. (DP-15) ...... 144 Garcia K. (BB-13) ...... 57 Fitzsimmons M.R. (BE-12) ...... 64 Frömter R. (DG-07) ...... 139 Fullerton E.E. (ES-08) ...... 186 Garcia K. (DU-06) ...... 154 Flade S.D. (GH-01) ...... 246 Frömter R. (EA-05) ...... 162 Fullerton E.E. (ES-09) ...... 186 Garcia K. (FU-10) ...... 225 Flatau A.B. (CF-02) ...... 99 Frougier J. (HB-09) ...... 266 Fullerton E.E. (FC-04) ...... 201 Garcia K. (HC-06) ...... 268 Flatau A.B. (CF-05) ...... 99 Fruchart D. (ER-13) ...... 184 Fullerton E.E. (GD-01) ...... 237 Garcia L.M. (DE-01) ...... 133 Flatau A.B. (CF-07) ...... 100 Fruchart O. (AU-14) ...... 48 Fullerton E.E. (GP-03) ...... 249 Garcia M. (GS-12) ...... 257 Flatau A.B. (FC-11) ...... 202 Fruchart O. (DB-03) ...... 126 Funtov K. (ER-11) ...... 184 Garcia-Arribas A. (GG-02) ...... 245 Flatté M.E. (CA-04) ...... 90 Fruchart O. (FC-05) ...... 201 Furdyna J. (AB-07) ...... 19 Garcia-Flores A.F. (AQ-15) ...... 39 Flattè M.E. (GH-13) ...... 248 Fry P.W. (BB-10) ...... 56 Furdyna J. (GU-14) ...... 261 García-Flores A.F. (DQ-13) ...... 146 Fletcher J. (FU-05) ...... 224 Fu E. (FG-08) ...... 209 Furubayashi T. (AB-09) ...... 19 García-Hernández M. (FR-02) . . . . .217 Fletcher S.L. (DS-10) ...... 150 Fu H. (ET-01) ...... 187 Furubayashi T. (AP-14) ...... 37 Garcia-Hernandez M. (GS-12) . . . . .257 Flint C. (BE-12) ...... 64 Fu H. (FQ-06) ...... 216 Furubayashi T. (CH-11) ...... 106 Garcia-Mochales P. (FC-09) ...... 201 Florez S. (HF-03) ...... 274 Fu J. (FG-03) ...... 209 Furubayashi T. (HC-13) ...... 269 Garcia-Muñoz J. (AE-10) ...... 26 Florez S. (HF-11) ...... 275 Fu P. (EW-07) ...... 195 Furukawa T. (AS-10) ...... 43 Garcia-Muñoz J. (HH-02) ...... 278 Florez S.H. (HF-06) ...... 274 Fu S. (BX-11) ...... 89 Furukawa Y. (AQ-10) ...... 38 Garcia-Sanchez F. (CB-02) ...... 91 Floro J. (AF-02) ...... 27 Fu S. (DB-04) ...... 126 Furuta A. (DT-14) ...... 153 Garcia-Sanchez F. (CP-12) ...... 108 Foerster M. (BG-02) ...... 68 Fu W. (AW-07) ...... 51 Furuta M. (BT-14) ...... 82 Garcia-Sanchez F. (EH-15) ...... 178 Foerster M. (CF-09) ...... 100 Fu W. (CT-17) ...... 116 Furuta M. (CT-14) ...... 116 Garcia-Vazquez V. (AP-07) ...... 36 Folcke E. (DF-10) ...... 137 Fu W. (CV-04) ...... 120 Furuta M. (HF-04) ...... 274 Gardner D.S. (BR-01) ...... 77 Folven E. (FP-16) ...... 214 Fu Y. (DG-01) ...... 138 Fushimi T. (CR-11) ...... 112 Gardner D.S. (EG-07) ...... 174 Fonin M. (HE-12) ...... 273 Fuhrmann P. (EC-11) ...... 166 Futamoto M. (AG-14) ...... 32 Gardner D.S. (FP-08) ...... 213 Fontcuberta J. (BE-05) ...... 63 Fujieda M. (CH-01) ...... 104 Futamoto M. (AP-02) ...... 35 Garitezi T.M. (CS-05) ...... 114 Fontcuberta J. (CE-01) ...... 97 Fujii Y. (GU-04) ...... 259 Futamoto M. (DV-08) ...... 157 Garlatti E. (AQ-10) ...... 38 Fontcuberta J. (EB-01) ...... 163 Fujikawa Y. (BP-11) ...... 74 Garlea V.O. (HH-01) ...... 278 Fontcuberta J. (FC-10) ...... 202 Fujikura M. (ER-07) ...... 183 - G - Garnache A. (HB-09) ...... 266 Forbes C.M. (EU-06) ...... 190 Fujimura N. (AE-05) ...... 26 Garraud A. (GF-11) ...... 244 Forgan E.M. (BF-06) ...... 66 Fujino Y. (BS-01) ...... 79 Gabay A. (DF-05) ...... 136 Garraud N. (GP-13) ...... 250 Forget A. (AE-09) ...... 26 Fujino Y. (BS-08) ...... 80 Gabay A. (GV-02) ...... 261 Garshelis I.J. (ER-16) ...... 184 Forghani B. (CR-12) ...... 112 Fujisaki K. (ER-04) ...... 183 Gabay A.M. (FR-04) ...... 217 Gasi T. (AB-11) ...... 20 Forker M. (DQ-01) ...... 145 Fujishiro H. (CQ-11) ...... 110 Gabay D. (BT-06) ...... 82 Gaspar J.F. (BH-08) ...... 71 Fowley C. (CU-07) ...... 118 Fujishiro H. (EQ-13) ...... 182 Gaddy J. (BD-02) ...... 60 Gassman P. (EP-14) ...... 180 Fox M.A. (GH-06) ...... 247 Fujita S. (BA-05) ...... 55 Gage E. (FE-07) ...... 205 Gaudin G. (AS-14) ...... 43 Fradin F.Y. (DU-12) ...... 155 Fujun Y. (BP-13) ...... 74 Gaidis M.C. (GC-06) ...... 236 Gaudin G. (AU-08) ...... 47 Fradin F.Y. (FP-13) ...... 214 Fukami S. (BB-11) ...... 57 Gaita-Ariño A. (FD-02) ...... 202 Gaudin G. (AU-13) ...... 48 Fraile Rodriguez A. (DE-01) ...... 133 Fukami S. (BS-02) ...... 79 Gajbhiye N.S. (EP-07) ...... 179 Gaudin G. (DB-05) ...... 126 Franco Jr A. (EX-03) ...... 196 Fukami S. (CD-05) ...... 95 Galbiati M. (DC-11) ...... 129 Gaudin G. (DU-06) ...... 154 Franco N. (DW-04) ...... 158 Fukami S. (CD-06) ...... 96 Galbiati M. (HC-10) ...... 269 Gaudin G. (GE-12) ...... 242 Franco R. (DQ-05) ...... 145 Fukami S. (DC-09) ...... 129 Gallagher B. (DP-07) ...... 143 Gaudin G. (HC-01) ...... 267 Franco V. (AR-12) ...... 41 Fukami S. (DC-10) ...... 129 Gallagher R. (AF-06) ...... 28 Gaudisson T. (AD-01) ...... 23 Franco V. (CG-12) ...... 103 Fukami S. (DH-09) ...... 141 Gallais Y. (AE-09) ...... 26 Gaudisson T. (ED-11) ...... 168 Franco V. (EF-14) ...... 173 Fukami S. (FU-07) ...... 224 Gallardo C. (AH-08) ...... 34 Gaupp A. (ED-02) ...... 167 Franco V. (EF-15) ...... 173 Fukuma Y. (AC-09) ...... 22 Gallardo C. (AR-10) ...... 40 Gautam S. (HC-08) ...... 268 Franco V. (FR-06) ...... 218 Fukumoto H. (AS-10) ...... 43 Gambardella P. (FA-02) ...... 197 Gautier E. (BH-02) ...... 70 Franke K. (HA-03) ...... 264 Fukumoto M. (CP-05) ...... 107 Gan H. (GT-04) ...... 258 Gautier E. (HC-01) ...... 267 Franken J. (DB-08) ...... 126 Fukunaga H. (BR-12) ...... 78 Gandha K.H. (AR-11) ...... 40 Gavilano J. (BF-06) ...... 66 Franken J.H. (BB-06) ...... 56 Fukunaga H. (BV-13) ...... 87 Gandha K.H. (BH-13) ...... 72 Gazquez J. (BE-04) ...... 63 Franken J.H. (BG-02) ...... 68 Fukunaga H. (DG-06) ...... 138 Gandra F.G. (CQ-07) ...... 109 Gazquez J. (DE-01) ...... 133 296 PROGRAM PROGRAM 297

Ge H. (GV-01) ...... 261 Givord D. (FF-08) ...... 207 Gray A.X. (FC-02) ...... 200 Gupta S. (AX-14) ...... 54 Gehring G. (AX-09) ...... 53 Glasbrenner J.K. (FX-04) ...... 230 Gray A.X. (HH-05) ...... 279 Gupta S. (CD-13) ...... 97 Gehring G.A. (DD-09) ...... 132 Glushchenko A. (AT-08) ...... 45 Gray M. (BE-10) ...... 64 Gupta S. (EF-12) ...... 172 Gehring G.A. (GH-06) ...... 247 Gobbi M. (BP-16) ...... 74 Gray M.T. (EQ-10) ...... 182 Gupta S. (FQ-07) ...... 216 Geilhufe J. (BG-02) ...... 68 Goering E. (DF-05) ...... 136 Greaves S. (BT-03) ...... 81 Gupta S. (GT-08) ...... 258 Geisler M.P. (FX-05) ...... 230 Goering E. (HE-12) ...... 273 Greaves S.J. (GW-04) ...... 263 Gupta S. (HF-10) ...... 275 Geiss R. (EE-03) ...... 169 Goering E.J. (BW-09) ...... 88 Grepstad J.K. (FP-16) ...... 214 Gurney B. (EE-02) ...... 169 Geiss R. (EW-15) ...... 196 Goerlitz D. (DX-04) ...... 160 Grigoras M. (EE-11) ...... 170 Gurney B. (HF-03) ...... 274 Gemming S. (BG-01) ...... 67 Goerlitz D. (GP-14) ...... 250 Grijalva Castillo M.C. (BQ-10) . . . . .76 Gurney B.A. (EH-01) ...... 175 Geng D. (DR-13) ...... 149 Goff J.P. (AD-12) ...... 24 Grimaldi E. (DA-03) ...... 125 Gusakova D. (CP-12) ...... 108 Geng D. (EF-09) ...... 172 Goh J. (FE-03) ...... 204 Grimaldi E. (EH-12) ...... 177 Gusakova D. (EH-15) ...... 178 Geng W. (BV-10) ...... 86 Goh J.K. (GR-05) ...... 254 Grin Y. (BD-03) ...... 60 Guslienko K. (DA-05) ...... 125 Geng W. (GV-03) ...... 261 Goldstein J.I. (DF-01) ...... 135 Grollier J. (BG-04) ...... 68 Gutfleisch O. (AF-09) ...... 28 Geng Y. (AE-01) ...... 25 Goldstein J.I. (DF-06) ...... 136 Grollier J. (CB-01) ...... 91 Gutfleisch O. (BF-07) ...... 66 Geng Y. (AE-07)* ...... 26 Goldstein J.I. (DV-04) ...... 156 Grollier J. (DA-03) ...... 125 Gutfleisch O. (CF-14) ...... 101 Geng Y. (CG-10) ...... 103 Gollapudi S. (AD-02) ...... 23 Grollier J. (DB-09) ...... 127 Gutfleisch O. (DF-07) ...... 136 George J. (HB-09) ...... 266 Golmar F. (BP-16) ...... 74 Grollier J. (EH-12) ...... 177 Gutfleisch O. (DF-08) ...... 136 George S. (DD-09) ...... 132 Gomes A.S. (AX-07) ...... 53 Grollier J. (FU-14) ...... 225 Gutfleisch O. (EF-03) ...... 171 George T. (BT-16) ...... 83 Gomes J.A. (DV-10) ...... 157 Grollier J. (GP-05) ...... 249 Gutfleisch O. (FF-10) ...... 207 George T.A. (HF-02) ...... 274 Gomez A. (HE-06) ...... 272 Grübel G. (EA-05) ...... 162 Gutfleisch O. (HG-01) ...... 276 George Z. (FT-09) ...... 222 Gomi M. (DS-06) ...... 150 Grundler D. (BU-08) ...... 84 Gutiérrez D. (BE-05) ...... 63 Geppert C.C. (HB-08) ...... 266 Gonçalves A.M. (CB-09) ...... 92 Grutter A.J. (AD-02) ...... 23 Gutièrrez D. (CE-01) ...... 97 Ger T. (BW-07) ...... 88 Gonçalves A.M. (CU-15) ...... 119 Grutter A.J. (BE-12) ...... 64 Gutt C. (EA-05) ...... 162 Ger T. (CW-05) ...... 122 Gonçalves F. (AD-11) ...... 24 Grütter P.H. (FC-09) ...... 201 Ger T. (EW-07) ...... 195 Gonçalves F. (BC-06) ...... 58 Grychtol P. (EU-08) ...... 190 - H - Ger T. (FP-10) ...... 214 Gonçalves F. (DB-11) ...... 127 Grychtol P. (FB-05) ...... 199 Gerfer A. (DG-12) ...... 139 Gonder C. (DS-10) ...... 150 Gschneidner K.A. (AP-12) ...... 36 Ha P.T. (EW-03) ...... 194 Gerhard F. (EH-02) ...... 176 Gong R. (DS-12) ...... 150 Gschneidner K.A. (EF-10) ...... 172 Hadimani R.L. (AP-12) ...... 36 Gervits N. (DW-07) ...... 159 Gong R. (FG-04) ...... 209 Gschneidner, Jr. K.A. (BD-01) ...... 60 Hadimani R.L. (BQ-09) ...... 76 Ghahremani M. (CF-13) ...... 101 Gong W. (DS-12) ...... 150 Gschneidner, Jr. K.A. (DQ-03) . . . . .145 Hadimani R.L. (CQ-15) ...... 110 Ghahremani M. (GQ-15) ...... 253 Gong W. (EF-09) ...... 172 Gschneidner, Jr. K.A. (DQ-09) . . . . .146 Hadimani R.L. (FH-12) ...... 212 Ghasemi A. (EX-02) ...... 196 Gong W. (EW-05) ...... 194 Guagliardo P. (ET-04) ...... 187 Hadimani R.L. (FQ-06) ...... 216 Ghatwai P. (AF-02) ...... 27 Gonzalez Barba P. (DH-06) ...... 140 GuangCheng X. (ES-05) ...... 185 Hadimani R.L. (GR-09) ...... 254 Ghigo G. (GQ-09) ...... 252 Gonzalez J. (CG-09) ...... 103 Gubbins M.A. (ET-13) ...... 188 Hadj Larbi Y. (AS-14) ...... 43 Ghoreyshi A. (BT-15) ...... 82 Gonzalez J. (FG-01) ...... 208 Gubbins M.A. (FT-06) ...... 222 Hadjiapanayis G. (DF-05) ...... 136 Ghosh A. (BC-01) ...... 58 Gonzalez Oyarce A.L. (AU-11) . . . . .47 Gubbiotti G. (AC-02) ...... 20 Hadjipanayis G. (DF-07) ...... 136 Ghosh J. (HB-03) ...... 265 González-Chávez D.E. (BU-13) . . . . .85 Gubbiotti G. (AC-05) ...... 21 Hadjipanayis G. (GV-02) ...... 261 Ghosh S. (DE-04) ...... 133 Gonzalez-Legarreta L. (CG-09) . . . .103 Gubbiotti G. (AH-02) ...... 33 Hadjipanayis G.C. (AF-06) ...... 28 Ghosh S. (FD-02) ...... 202 Gopman D.B. (DP-15) ...... 144 Gubbiotti G. (BU-08) ...... 84 Hadjipanayis G.C. (BV-04) ...... 86 Gifford J.A. (AB-05) ...... 19 Gorgoi M. (DC-02) ...... 128 Gubbiotti G. (BU-10) ...... 84 Hadjipanayis G.C. (EE-05) ...... 170 Gilbert D.A. (AD-05) ...... 23 Gorgoi M. (GH-01) ...... 246 Gubbiotti G. (CF-03) ...... 99 Hadjipanayis G.C. (FR-04) ...... 217 Gilbert D.A. (AF-01) ...... 27 Gorji Ghalamestani S. (CR-13) . . . . .112 Guenther J. (AB-07) ...... 19 Hahn C. (BC-09) ...... 59 Gilbert D.A. (FP-11) ...... 214 Görlitz D. (BW-08) ...... 88 GuiJun L. (ES-05) ...... 185 Haidar M. (CP-09) ...... 107 Gilbert D.A. (HE-06) ...... 272 Gornakov V. (GE-07) ...... 241 GuiJun L. (FX-02) ...... 230 Haldar A. (BG-09) ...... 69 Gilbert E.P. (BF-06) ...... 66 Gorria P. (EF-15) ...... 173 Guillot M. (DG-11) ...... 139 Hallal A. (GB-07) ...... 234 Gilbert I. (DD-03) ...... 131 Goto R. (AV-01) ...... 48 Guillot M. (ER-13) ...... 184 Hallal A. (GD-09) ...... 239 Gilbert M. (ED-02) ...... 167 Goto T. (EQ-09) ...... 181 Guillou F. (CF-11) ...... 100 Hamadeh A. (EH-09) ...... 177 Giles C. (CQ-09) ...... 110 Goto T. (GD-05) ...... 238 Guimarães A.O. (FQ-01) ...... 215 Hamadeh A. (GP-05) ...... 249 Giles C. (ED-01) ...... 167 Goto W. (DV-12) ...... 157 Gunduz Akdogan N. (AF-08) ...... 28 Hämäläinen S. (HA-03) ...... 264 Gilks D. (BE-11) ...... 64 Goto Y. (CH-01) ...... 104 Gunduz Akdogan N. (AV-15) ...... 50 Hamasaki Y. (ES-02) ...... 185 Gilks D. (GH-02) ...... 246 Gotschall T. (EF-03) ...... 171 Günter C.M. (BG-02) ...... 68 Hamaya K. (BP-12) ...... 74 Gilks D. (GH-07) ...... 247 Gottlob D. (FC-12) ...... 202 Güntherodt G. (GC-12) ...... 237 Hamaya K. (HB-04) ...... 265 Gilks D. (HC-12) ...... 269 Gottschall T. (CF-14) ...... 101 Guo A. (EG-05) ...... 174 Hameyer K. (BQ-11) ...... 76 Gillette S. (CX-09) ...... 123 Gottwald M. (DC-07) ...... 129 Guo D. (CH-08) ...... 105 Hammel C.P. (BC-13) ...... 59 Gillette S.M. (DS-02) ...... 149 Gottwald M. (ES-08) ...... 186 Guo D. (ES-10) ...... 186 Hammel C.P. (CU-08) ...... 118 Giordano A. (DH-02) ...... 140 Gottwald M. (ES-09) ...... 186 Guo D. (FS-06) ...... 220 Hammel P. (BC-12) ...... 59 Giovannini L. (AC-03) ...... 21 Gottwald M. (GD-01) ...... 237 Guo D. (FS-10) ...... 220 Hammel P.C. (GC-02) ...... 235 Giovannini L. (AC-05) ...... 21 Götz G. (GR-02) ...... 254 Guo F. (CU-14) ...... 119 Hamrle J. (AT-06) ...... 44 Giovannini L. (BU-10) ...... 84 Gould C. (EH-02) ...... 176 Guo F. (DU-08) ...... 154 Hamrle J. (ED-02) ...... 167 Giri A. (HD-08) ...... 271 Gourgon C. (BU-15) ...... 85 Guo F. (GR-13) ...... 255 Han D. (AC-12) ...... 22 Girod S. (GP-05) ...... 249 Goyette R. (BE-04) ...... 63 Guo H. (BG-13) ...... 70 Han D. (EU-16) ...... 191 Girt E. (AG-08) ...... 31 Goyette R.J. (BP-15) ...... 74 Guo S. (EV-05) ...... 192 Han G. (AP-13) ...... 36 Girt E. (AP-04) ...... 35 Gozdur R. (AW-09) ...... 51 Guo S. (EV-10) ...... 193 Han G. (AU-02) ...... 46 Girt E. (CC-08) ...... 94 Gräfe J. (BW-09) ...... 88 Guo S. (EV-12) ...... 193 Han G. (EG-10) ...... 174 Girt E. (CD-13) ...... 97 Granado E. (DQ-13) ...... 146 Guo S. (GF-08) ...... 243 Han G. (FX-08) ...... 231 Girt E. (GC-03) ...... 235 Granovsky A. (FQ-11) ...... 216 Guo Y. (BQ-07) ...... 75 Han G. (GU-05) ...... 260 Girt E. (HF-12) ...... 275 Grant A. (CU-16) ...... 119 Guo Y. (CT-17) ...... 116 Han H. (DB-10) ...... 127 Giussani A. (ED-03) ...... 167 Grant T. (CS-04) ...... 113 Guo Z. (ES-13) ...... 186 Han H. (ET-01) ...... 187 Givord D. (AF-08) ...... 28 Grant T. (CS-05) ...... 114 Guo Z. (GV-13) ...... 262 Han K. (GV-09) ...... 262 Givord D. (AV-11) ...... 49 Graves C. (DU-05) ...... 154 Gupta A. (BE-08) ...... 63 Han S. (CD-04) ...... 95 Givord D. (AV-15) ...... 50 Graves C. (HF-11) ...... 275 Gupta J. (EW-04) ...... 194 Han T. (FS-08) ...... 220 Givord D. (EW-14) ...... 196 Graves C.E. (FB-04) ...... 199 Gupta S. (AH-12) ...... 34 Han T. (GA-04) ...... 232 298 PROGRAM PROGRAM 299

Han T. (GS-06) ...... 256 Hauet T. (BG-08) ...... 69 Hernandez Paz J. (DV-05) ...... 156 Hoarau C. (BG-10) ...... 69 Han X. (AW-13) ...... 52 Hauet T. (DC-04) ...... 128 Hernández Paz J.F. (FQ-02) ...... 215 Hobosyan M. (BH-11) ...... 72 Han X. (DS-03) ...... 149 Hauser A. (GC-02) ...... 235 Hernando B. (CG-09) ...... 103 Hockel J. (CF-09) ...... 100 Han X. (GU-03) ...... 259 Hayashi M. (AG-11) ...... 32 Heron J. (EB-01) ...... 163 Hockel J.L. (GB-06) ...... 233 Han X.F. (DV-02) ...... 156 Hayashi M. (FA-05) ...... 198 Herranz G. (CE-03) ...... 97 Hodges M.H. (BB-10) ...... 56 Han Z. (DR-13) ...... 149 Hayashi N. (DU-04) ...... 154 Herranz G. (FC-10) ...... 202 Hoefer M. (CB-07) ...... 92 Haney P.M. (FA-04) ...... 198 Hayashi N. (FU-06) ...... 224 Herrera Diez L. (BB-13) ...... 57 Hoefer M. (DA-02) ...... 124 Hangarter C. (GR-13) ...... 255 Hayashi Y. (DV-12) ...... 157 Herrera Diez L. (DU-06) ...... 154 Hoefer M.A. (CB-06) ...... 91 Hanna C. (EQ-11) ...... 182 Hayashibara H. (HD-07) ...... 271 Herrera Diez L. (FU-10) ...... 225 Hoefer M.A. (DA-01) ...... 124 Hansen O. (BS-14) ...... 81 Hayward T.J. (AU-09) ...... 47 Herrera-Diez L. (HC-06) ...... 268 Hoefer M.A. (GP-01) ...... 249 Hansen O. (ET-17) ...... 189 Hayward T.J. (BB-10) ...... 56 Herrero-Albillos J. (FC-02) ...... 200 Hoelzel M. (GQ-03) ...... 252 Hanyu T. (CD-05) ...... 95 Hayward T.J. (FU-01) ...... 224 Herrero-Martín J. (HH-02) ...... 278 Hoffmann A. (BC-02) ...... 58 Hanyu T. (CD-09) ...... 96 He C. (BE-04) ...... 63 Hertel R. (DX-11) ...... 161 Hoffmann A. (FP-11) ...... 214 Hanyu T. (DC-01) ...... 128 He J. (AR-04) ...... 40 Hesjedal T. (AH-11) ...... 34 Hofmann M. (ED-10) ...... 168 Hanyu T. (GT-10) ...... 258 He K. (AP-13) ...... 36 Hesjedal T. (GP-16) ...... 251 Hofmann M. (GQ-03) ...... 252 Hao G. (BR-03) ...... 77 He K. (DU-11) ...... 155 Hesjedal T. (GT-03) ...... 258 Holý V. (CF-04) ...... 99 Hao H. (DS-02) ...... 149 He L. (EB-02) ...... 163 Hetaimish R. (HG-02) ...... 276 Holt M.V. (FC-04) ...... 201 Hao L. (AP-08) ...... 36 He L. (EW-09) ...... 195 Hevroni A. (DE-06) ...... 134 Homrich R.P. (GG-11) ...... 246 Hao L. (DT-09) ...... 152 He S. (EH-06) ...... 176 Heyderman L. (DD-04) ...... 131 Honda N. (GW-08) ...... 264 Hao Z. (AR-01) ...... 39 He S. (EQ-04) ...... 181 Heyderman L.J. (DD-01) ...... 130 Honda Y. (FX-03) ...... 230 Hara A. (GW-07) ...... 264 He W. (AS-05) ...... 42 Heyderman L.J. (HC-03) ...... 267 Honecker D. (BF-06) ...... 66 Harada K. (ET-08) ...... 188 He W. (AS-13) ...... 43 Hiblot G. (BB-14) ...... 57 Hong D. (CV-06) ...... 120 Harada M. (FF-04) ...... 206 He W. (AW-10) ...... 51 Hicken R.J. (DB-12) ...... 127 Hong F. (CS-08) ...... 114 Harashima Y. (BF-02) ...... 65 He W. (DS-09) ...... 150 Hicken R.J. (EH-10) ...... 177 Hong J. (BG-11) ...... 69 Hardeman R. (ET-13) ...... 188 He X. (DS-15) ...... 151 Hicken R.J. (FB-10) ...... 200 Hong J. (CD-04) ...... 95 Häring F. (BW-09) ...... 88 He X. (FP-14) ...... 214 Hicken R.J. (FT-06) ...... 222 Hong J. (DC-12) ...... 130 Harmon N.J. (CA-04) ...... 90 He X. (HG-05) ...... 277 Hickey B. (EC-09) ...... 166 Hong J. (DF-08) ...... 136 Harms J. (BA-02) ...... 54 He Y. (ER-03) ...... 183 Hickey B.J. (CP-08) ...... 107 Hong J. (DP-04) ...... 143 Harms J. (GC-06) ...... 236 Heald S. (GH-06) ...... 247 Hickey B.J. (EC-05) ...... 165 Hong J. (GE-05) ...... 240 Harris V. (CX-09) ...... 123 Heald S.M. (ED-04) ...... 167 Hidalgo P. (DW-05) ...... 158 Hong J. (GE-08) ...... 241 Harris V.G. (AV-07) ...... 49 Heczko O. (GQ-05) ...... 252 Hiebert W.K. (BG-12) ...... 69 Hong J. (GU-10) ...... 260 Harris V.G. (AV-08) ...... 49 Hehn M. (AG-01) ...... 30 Hiemenz G.J. (FW-02) ...... 228 Hong J.H. (FH-13) ...... 212 Harris V.G. (CX-06) ...... 123 Hehn M. (FB-08) ...... 199 Hilinski E. (ER-03) ...... 183 Hong M. (HB-07) ...... 266 Harris V.G. (DS-02) ...... 149 Hehn M. (GB-15) ...... 235 Hill S. (FD-02) ...... 202 Hong S. (GQ-13) ...... 253 Harris V.G. (ER-12) ...... 184 Hehn M. (GD-01) ...... 237 Hillebrands B. (AC-08) ...... 21 Hong S. (GQ-14) ...... 253 Harris V.G. (EX-09) ...... 197 Heil M. (BX-02) ...... 88 Hillebrands B. (AC-11) ...... 22 Hong Y. (FG-13) ...... 210 Harris V.G. (FV-01) ...... 226 Heiliger C. (DC-13) ...... 130 Hillebrands B. (EC-02) ...... 165 Hong Y. (HD-03) ...... 270 Harris V.G. (FV-02) ...... 226 Heiliger C. (EB-05) ...... 163 Hillebrands B. (EC-11) ...... 166 Honjo H. (BS-02) ...... 79 Harris V.G. (FV-05) ...... 227 Heiliger C. (GU-07) ...... 260 Hillsberry D.A. (EQ-11) ...... 182 Honjo H. (CD-05) ...... 95 Harrison R. (DE-05) ...... 134 Heim K. (FE-07) ...... 205 Hinata S. (BT-02) ...... 81 Honjo H. (CD-06) ...... 96 Harrison R. (HE-02) ...... 272 Heiman D. (AB-02) ...... 18 Hinata S. (HF-09) ...... 275 Honjo H. (DC-01) ...... 128 Hartmann R. (FB-04) ...... 199 Heiman D. (DV-14) ...... 157 Hine N. (BD-05) ...... 60 Hono K. (AP-14) ...... 37 Harward I. (CX-04) ...... 123 Heiman D. (ED-12) ...... 169 Hines A. (FR-03) ...... 217 Hono K. (BT-13) ...... 82 Harward I. (EQ-07) ...... 181 Heiman D. (EX-09) ...... 197 Hingant T. (BB-13) ...... 57 Hono K. (CH-11) ...... 106 Harward I. (FG-11) ...... 210 Heiman D. (GH-12) ...... 248 Hingant T. (DU-06) ...... 154 Hono K. (DV-06) ...... 156 Harward I. (GD-02) ...... 238 Heinonen O. (EH-05) ...... 176 Hinzke D. (CB-04) ...... 91 Hono K. (ER-09) ...... 183 Hase T.A. (GE-06) ...... 241 Heinonen O. (EH-11) ...... 177 Hinzke D. (EC-02) ...... 165 Hono K. (FF-02) ...... 206 Hasegawa N. (GP-11) ...... 250 Heinrich A.J. (FD-01) ...... 202 Hinzke D. (FB-06) ...... 199 Hono K. (FF-11) ...... 208 Hasegawa T. (CT-06) ...... 115 Heinrich B. (AG-08) ...... 31 Hioki K. (FF-11) ...... 208 Hono K. (FV-11) ...... 227 Hasegawa T. (ET-07) ...... 188 Heinrich B. (AP-04) ...... 35 Hioki K. (GF-04) ...... 243 Hono K. (GF-01) ...... 242 Hashi S. (AR-06) ...... 40 Heinrich B. (BC-02) ...... 58 Hioki K. (GF-13) ...... 244 Hono K. (GF-13) ...... 244 Hashi S. (AS-07) ...... 42 Heinrich B. (CC-08) ...... 94 Hiramatsu R. (EU-01) ...... 189 Hono K. (GV-07) ...... 262 Hashi S. (DV-12) ...... 157 Heinrich B. (GC-03) ...... 235 Hiramatsu R. (FU-07) ...... 224 Hono K. (HC-13) ...... 269 Hashi S. (EW-10) ...... 195 Heinrich B. (HF-12) ...... 275 Hirayama Y. (DV-06) ...... 156 Hordagoda M. (BE-09) ...... 64 Hashimoto R. (AT-09) ...... 45 Heitmann T. (BD-02) ...... 60 Hirohata A. (AD-13) ...... 25 Hordagoda M. (DS-14) ...... 151 Hashmi A. (GU-10) ...... 260 Hejtmanek J. (AQ-03) ...... 37 Hirohata A. (FP-09) ...... 213 Horikawa R. (BV-13) ...... 87 Haskel D. (ED-01) ...... 167 Hejtmanek J. (CQ-11) ...... 110 Hirohata A. (FX-10) ...... 231 Horwath J. (BV-02) ...... 85 Hasnip P. (HC-05) ...... 268 Heldt G. (HC-03) ...... 267 Hirohata A. (GH-07) ...... 247 Hoser A. (DG-11) ...... 139 Hasnip P.J. (GH-07) ...... 247 Hellman F. (CC-13) ...... 94 Hirosawa S. (FF-02) ...... 206 Hosko J. (EF-04) ...... 171 Hastings J.T. (DD-06) ...... 131 Hellman F. (FC-02) ...... 200 Hirosawa S. (GF-01) ...... 242 Hosono H. (GH-02) ...... 246 Hastings T. (AQ-04) ...... 38 Hellman F. (FC-03) ...... 201 Hiroyuki E. (BP-04) ...... 73 Hosoya H. (BS-10) ...... 80 Hastings T. (BC-04) ...... 58 Hellwig O. (BT-07) ...... 82 Hjörvarsson B. (AF-07) ...... 28 Hossain S. (HH-04) ...... 278 Hata H. (EU-01) ...... 189 Hellwig O. (BU-02) ...... 83 Hjörvarsson B. (DG-01) ...... 138 Hossain Z. (ET-16) ...... 189 Hata K. (BW-02) ...... 87 Hellwig O. (HF-11) ...... 275 Hjörvarsson B. (GE-06) ...... 241 Hotta A. (CT-14) ...... 116 Hata K. (HD-09) ...... 271 Helm M. (GH-14) ...... 248 Hla S. (AA-05) ...... 18 Hotta A. (DT-15) ...... 153 Hatada A. (AS-10) ...... 43 Hendren W.R. (ET-13) ...... 188 Ho C. (BP-02) ...... 72 Hotta A. (FT-10) ...... 222 Hatayama M. (DT-15) ...... 153 Hendren W.R. (EU-06) ...... 190 Ho H.C. (FE-08) ...... 205 Hotta A. (HF-04) ...... 274 Hatayama M. (FE-06) ...... 205 Hennen T. (HF-06) ...... 274 Ho K. (DF-12) ...... 137 Hotta K. (FE-09) ...... 205 Hattori A. (FF-11) ...... 208 Henrichsen H.H. (BS-14) ...... 81 Ho P. (AP-13) ...... 36 Hotta Y. (DV-08) ...... 157 Hattori A. (GF-04) ...... 243 Henrichsen H.H. (ET-17) ...... 189 Ho S. (AT-15) ...... 46 Hou Broutin Y. (FH-10) ...... 212 Hattori A. (GF-13) ...... 244 Herbst J. (BF-14) ...... 67 Ho S. (AW-07) ...... 51 Hou Y. (BW-01) ...... 87 Hattrick-Simpers J. (FF-06) ...... 207 Hermenau J. (GB-08) ...... 234 Ho S. (CV-04) ...... 120 Hou Y. (EE-04) ...... 169 300 PROGRAM PROGRAM 301

Hou Y. (HE-03) ...... 272 Huang C. (FP-10) ...... 214 Iihama S. (AP-06) ...... 35 Ishikawa S. (DC-09) ...... 129 Hou Z. (AS-09) ...... 42 Huang E.Y. (FE-10) ...... 205 Iihama S. (CU-06) ...... 118 Ishikawa S. (DC-10) ...... 129 Hou-Broutin Y. (BH-02) ...... 70 Huang H. (AS-15) ...... 43 Iihama S. (CU-11) ...... 118 Ishimaru S. (CQ-05) ...... 109 Houanche R. (DU-01) ...... 153 Huang H. (AW-01) ...... 50 Iihama S. (FB-11) ...... 200 Ishio S. (CT-06) ...... 115 Houssameddine D. (BA-01) ...... 54 Huang H. (CU-10) ...... 118 Ikeda K. (DP-05) ...... 143 Ishio S. (ET-07) ...... 188 Howe B. (ES-01) ...... 185 Huang H. (DE-11) ...... 135 Ikeda S. (BB-11) ...... 57 Ishiyama K. (AR-06) ...... 40 Howe B. (ES-03) ...... 185 Huang H. (FH-05) ...... 211 Ikeda S. (BS-02) ...... 79 Ishiyama K. (AS-07) ...... 42 Hozumi T. (FV-11) ...... 227 Huang H. (FP-02) ...... 213 Ikeda S. (CD-05) ...... 95 Ishiyama K. (DV-12) ...... 157 Hrabec A. (BC-06) ...... 58 Huang J. (EH-06) ...... 176 Ikeda S. (DC-01) ...... 128 Ishiyama K. (ER-07) ...... 183 Hrabec A. (DD-05) ...... 131 Huang K. (AG-10) ...... 31 Ikeda S. (DC-09) ...... 129 Ishiyama K. (EW-10) ...... 195 Hrabovsky D. (CX-04) ...... 123 Huang K. (AP-05) ...... 35 Ikeda S. (DC-10) ...... 129 Ishizawa R. (AD-13) ...... 25 Hrabovsky D. (GD-02) ...... 238 Huang K. (CC-05) ...... 93 Ikeda S. (DH-09) ...... 141 Iskhakov R.S. (DV-03) ...... 156 Hrdy M. (AF-02) ...... 27 Huang L. (EA-03) ...... 162 Ikeda S. (GT-10) ...... 258 Iskhakov R.S. (FR-10) ...... 218 Hrkac G. (FF-09) ...... 207 Huang P. (FE-04) ...... 204 Ikeda Y. (HF-03) ...... 274 Iskhakov R.S. (FR-12) ...... 218 Hrkac G. (FF-10) ...... 207 Huang Q. (DF-02) ...... 135 Ikeda Y. (HF-06) ...... 274 Islam M. (EG-05) ...... 174 Hrkac G. (HC-03) ...... 267 Huang Q. (FS-07) ...... 220 Ikeda Y. (HF-11) ...... 275 Isogami S. (GT-02) ...... 257 Hsiao C. (EP-10) ...... 179 Huang S. (AG-09) ...... 31 Ikegawa S. (CP-05) ...... 107 Iss C. (BH-02) ...... 70 Hsiao S. (DV-01) ...... 156 Huang S. (CR-06) ...... 111 Ikenaga E. (CS-01) ...... 113 Iss C. (FH-10) ...... 212 Hsiao S. (FS-05) ...... 220 Huang S. (DP-11) ...... 144 Im M. (BB-10) ...... 56 Ito A. (DR-12) ...... 148 Hsu C. (CR-14) ...... 112 Huang S. (DT-10) ...... 152 Im M. (BG-11) ...... 69 Ito E. (AG-05) ...... 30 Hsu C. (EG-04) ...... 174 Huang S. (EC-07) ...... 166 Im M. (GE-05) ...... 240 Ito J. (BA-05) ...... 55 Hsu C. (EG-11) ...... 175 Huang S. (EC-10) ...... 166 Im M. (GP-03) ...... 249 Ito K. (AB-10) ...... 19 Hsu C. (EG-14) ...... 175 Huang W. (GQ-01) ...... 251 Imamura H. (CB-11) ...... 92 Ito K. (GD-08) ...... 238 Hsu H. (DW-07) ...... 159 Huang X. (CQ-06) ...... 109 Imamura H. (CU-05) ...... 118 Ito S. (GG-05) ...... 245 Hsu H. (ER-11) ...... 184 Huang X. (CS-12) ...... 115 Imamura H. (DC-03) ...... 128 Ito W. (CH-07) ...... 105 Hsu H. (GS-06) ...... 256 Huang X. (GG-08) ...... 245 Imamura H. (DC-06) ...... 129 Itoh M. (ES-02) ...... 185 Hsu J. (AP-01) ...... 35 Huang Z. (DQ-08) ...... 146 Imamura H. (DP-13) ...... 144 Itoh S. (FF-12) ...... 208 Hsu J. (BR-06) ...... 77 Huba Z.J. (CW-06) ...... 122 Imamura H. (EH-13) ...... 178 Itoh T. (FG-05) ...... 209 Hsu J. (DT-03) ...... 151 Huba Z.J. (FV-04) ...... 227 Imamura H. (HH-06) ...... 279 Itoh Y. (GR-07) ...... 254 Hsu J. (DT-06) ...... 152 Hubel A. (BH-07) ...... 71 Imtiaz A. (CP-11) ...... 108 Ivanov V. (AE-10) ...... 26 Hsu J. (EP-03) ...... 178 Huber R. (BD-13) ...... 62 Inagaki K. (GR-10) ...... 255 Ivanov Y. (HE-10) ...... 273 Hsu J. (EP-09) ...... 179 Huber T. (HG-01) ...... 276 Inami N. (AG-11) ...... 32 Ivanov Y.P. (DG-03) ...... 138 Hsu J. (EX-01) ...... 196 Hueso L. (BP-16) ...... 74 Inami N. (BF-09) ...... 66 Ive T. (GH-10) ...... 248 Hsu J. (HC-04) ...... 268 Hughes B. (BB-03) ...... 55 Inami N. (FF-05) ...... 207 Ivkov R. (EW-11) ...... 195 Hsu T. (DW-07) ...... 159 Huh Y. (AT-13) ...... 45 Inami N. (FF-12) ...... 208 Iwahashi M. (GR-07) ...... 254 Hsu T. (ER-11) ...... 184 Huh Y. (DD-10) ...... 132 Inokuchi T. (AX-06) ...... 53 Iwamoto W.A. (AQ-15) ...... 39 Hsueh H. (FW-07) ...... 229 Hui Y. (CH-05) ...... 105 Inokuchi T. (HB-04) ...... 265 Iwamoto W.A. (AX-08) ...... 53 Hu A. (AH-10) ...... 34 Hung C. (GS-07) ...... 256 Inomata K. (AB-09) ...... 19 Iwane H. (BF-10) ...... 66 Hu B. (CX-06) ...... 123 Hung H. (HB-07) ...... 266 Inomata K. (DC-05) ...... 128 Iwano K. (AV-12) ...... 50 Hu B. (CX-09) ...... 123 Hung L. (BT-10) ...... 82 Inomata K. (GT-06) ...... 258 Iwano K. (BX-05) ...... 89 Hu D. (GV-05) ...... 262 Hung L. (DW-02) ...... 158 Inoue H. (ER-01) ...... 182 Iwasaka M. (EE-10) ...... 170 Hu F. (BV-05) ...... 86 Hung Y. (BU-06) ...... 84 Inoue J. (AF-03) ...... 28 Iwasaka M. (EW-08) ...... 195 Hu F. (BV-06) ...... 86 Husstedt H. (AW-12) ...... 51 Inoue J. (AF-13) ...... 29 Iwase A. (DT-07) ...... 152 Hu F. (EQ-06) ...... 181 Huth J.F. (CG-03) ...... 102 Inoue J. (ET-08) ...... 188 Iwata K. (ER-07) ...... 183 Hu F. (FQ-04) ...... 215 Hwang J. (FS-12) ...... 221 Inoue K. (GD-11) ...... 239 Iwata S. (BT-04) ...... 81 Hu F. (FQ-08) ...... 216 Hwang K. (ER-08) ...... 183 Inoue M. (AT-09) ...... 45 Iwata S. (CT-12) ...... 116 Hu F. (GQ-06) ...... 252 Hwang M.P. (FH-06) ...... 211 Inoue M. (FC-06) ...... 201 Iwata-Harms J.M. (AD-02) ...... 23 Hu F. (GV-04) ...... 261 Hwang S. (CR-15) ...... 113 Inoue M. (GD-05) ...... 238 Iwata-Harms J.M. (BE-01) ...... 62 Hu G. (BA-02) ...... 54 Hwang S. (FP-12) ...... 214 Inoue Y. (GC-11) ...... 237 Iyer K.K. (DS-04) ...... 149 Hu G. (CD-11) ...... 96 Hwang S. (FU-15) ...... 226 Ionescu A. (BD-05) ...... 60 Iyer K.K. (HH-07) ...... 279 Hu G. (EC-08) ...... 166 Hyodo K. (EB-09) ...... 164 Ipatov M. (CG-09) ...... 103 Izadkhah H. (GB-09) ...... 234 Hu G. (GC-06) ...... 236 Ipatov M. (CG-11) ...... 103 Izquierdo J. (GS-15) ...... 257 Hsu H.S. (CS-09) ...... 114 - I - Ipatov M. (FG-01) ...... 208 Izumida K. (AD-13) ...... 25 Hu J. (DT-12) ...... 152 Ipatov M. (FQ-11) ...... 216 Hu J. (EE-08) ...... 170 Iacocca E. (CB-07) ...... 92 Ipus J.J. (CG-12) ...... 103 - J - Hu K. (EW-07) ...... 195 Iacocca E. (CP-02) ...... 106 Ipus J.J. (FR-06) ...... 218 Hu K. (FP-10) ...... 214 Iacocca E. (DA-01) ...... 124 Iramina K. (GR-07) ...... 254 Jaafar M. (FC-09) ...... 201 Hu S. (EC-01) ...... 165 Iacocca E. (EH-05) ...... 176 Iriyama T. (GF-04) ...... 243 Jacobs B.S. (CQ-12) ...... 110 Hu W. (FW-02) ...... 228 Iacocca E. (EH-11) ...... 177 Irvine A. (DP-07) ...... 143 Jacques V. (BB-13) ...... 57 Hu W. (FW-11) ...... 229 Iacocca E. (EU-09) ...... 190 Irvine A.C. (GB-05) ...... 233 Jacques V. (DU-06) ...... 154 Hu X. (AF-06) ...... 28 Iavarone M. (DU-13) ...... 155 Isakov I. (BB-05) ...... 56 Jacquet E. (AE-03) ...... 25 Hu X. (DU-10) ...... 154 Iba Y. (AS-10) ...... 43 Ishaque Z. (AU-14) ...... 48 Jacquet E. (DC-11) ...... 129 Hu X. (FR-04) ...... 217 Ibach H. (EU-11) ...... 191 Ishibashi A. (FP-05) ...... 213 Jacquet E. (DH-15) ...... 142 Hu X.S. (FP-06) ...... 213 Ibarra R. (BB-12) ...... 57 Ishibashi S. (BF-02) ...... 65 Jacquot J. (AE-03) ...... 25 Hu Y. (EP-02) ...... 178 Ichikawa K. (DS-06) ...... 150 Ishibashi S. (GU-04) ...... 259 Jaffrès H. (HB-09) ...... 266 Huai Y. (CD-02) ...... 95 Ichinokura O. (GG-06) ...... 245 Ishibashi T. (FP-04) ...... 213 Jain S. (BT-07) ...... 82 Huai Y. (GT-04) ...... 258 Idzerda Y. (EE-03) ...... 169 Ishida M. (EC-06) ...... 166 Jain S. (DU-12) ...... 155 Huang C. (AP-01) ...... 35 Idzikowski B. (DD-11) ...... 132 Ishigaki T. (FF-05) ...... 207 Jain S. (FP-13) ...... 214 Huang C. (AV-13) ...... 50 Idzuchi H. (DP-01) ...... 142 Ishihara K. (CD-06) ...... 96 Jain S. (GP-06) ...... 249 Huang C. (CW-05) ...... 122 Iglesias O. (DE-01) ...... 133 Ishikawa H. (AV-05) ...... 49 Jakob G. (EC-02) ...... 165 Huang C. (DT-10) ...... 152 Iglesias-Freire O. (FC-09) ...... 201 Ishikawa M. (AX-06) ...... 53 Jakob G. (FS-01) ...... 219 Huang C. (EW-07) ...... 195 Ihara T. (DW-08) ...... 159 Ishikawa M. (HB-04) ...... 265 Jakubisova E.L. (CX-04) ...... 123 302 PROGRAM PROGRAM 303

Jakubisova E.L. (ET-03) ...... 187 Jeun M. (FH-06) ...... 211 Jin Z. (AP-17) ...... 37 Kaloshkin S. (AR-08) ...... 40 Jakubisova E.L. (GD-02) ...... 238 Jeun M. (FH-07) ...... 211 JinBo Y. (ES-05) ...... 185 Kaloshkin S.D. (CG-09) ...... 103 Jalil M.B. (BP-02) ...... 72 Jeyadevan B. (DV-10) ...... 157 JinBo Y. (FX-02) ...... 230 Kalousek R. (GP-03) ...... 249 Jalil M.B. (DU-09) ...... 154 Jheng H. (AT-10) ...... 45 Jing A. (DR-11) ...... 148 Kaltenbacher M. (AW-12) ...... 51 Jalil M.B. (FU-13) ...... 225 Jhon M.S. (FT-15) ...... 223 Jing Y. (AR-04) ...... 40 Kamalakar M.V. (GH-11) ...... 248 Jalil M.B.A. (BP-09) ...... 73 Jhon M.S. (FT-16) ...... 223 Jingjing J. (DR-11) ...... 148 Kamali Sarvestani N. (ED-06) . . . . .168 Jalink J. (DE-04) ...... 133 Jhon M.S. (FT-17) ...... 223 Jirak Z. (AQ-03) ...... 37 Kaman O. (AQ-03) ...... 37 Jamali M. (BC-11) ...... 59 Jhon M.S. (FT-18) ...... 223 Jirak Z. (CQ-11) ...... 110 Kaman O. (DE-10) ...... 134 Jamali M. (DH-13) ...... 142 Jhon M.S. (FT-19) ...... 223 Jirak Z. (DE-10) ...... 134 Kameno M. (HB-02) ...... 265 Jamali M. (EU-15) ...... 191 Ji C. (DE-11) ...... 135 Jo J. (AX-02) ...... 52 Kamil A. (FC-07) ...... 201 Jamali M. (GT-13) ...... 259 Ji Hoon Y. (EV-04) ...... 192 John J. (FV-09) ...... 227 Kammerer M. (BG-06) ...... 68 Jamer M.E. (GH-12) ...... 248 Jia J.L. (EX-07) ...... 197 Johnson D. (AF-10) ...... 29 Kan J. (DC-07) ...... 129 James R.D. (FV-10) ...... 227 Jia L. (EX-06) ...... 197 Johnson F. (GQ-15) ...... 253 Kan J.J. (CT-18) ...... 117 Jamet J. (AU-13) ...... 48 Jia L. (EX-08) ...... 197 Johnson M. (BB-08) ...... 56 Kan J.J. (ES-09) ...... 186 Jamet J. (DP-10) ...... 144 Jia N. (EP-02) ...... 178 Johnson M. (CD-04) ...... 95 Kan J.J. (GP-03) ...... 249 Jamet M. (AU-10) ...... 47 Jia Q. (EP-05) ...... 179 Johnston-Halperin E. (GC-02) . . . . .235 Kanai Y. (BT-03) ...... 81 Jamet M. (BB-07) ...... 56 Jia Q. (GS-02) ...... 256 Joisten H. (BH-02) ...... 70 Kanai Y. (CT-20) ...... 117 Jamet M. (BP-14) ...... 74 Jia T. (ED-08) ...... 168 Joisten H. (FH-10) ...... 212 Kanai Y. (GW-04) ...... 263 Jamet M. (BU-09) ...... 84 Jia W. (AR-01) ...... 39 Jonsson P. (AG-08) ...... 31 Kaneko U.F. (DQ-13) ...... 146 Jamet S. (DB-03) ...... 126 Jia X. (CG-14) ...... 104 Jonsson P. (HF-12) ...... 275 Kaneko Y. (FF-05) ...... 207 Jamet S. (FC-05) ...... 201 JianBo F. (ES-05) ...... 185 Joo D. (CV-06) ...... 120 Kaneko Y. (FF-12) ...... 208 Jan B. (BX-10) ...... 89 JianBo F. (FX-02) ...... 230 Joo S. (CD-04) ...... 95 Kang C. (FS-12) ...... 221 Jan G. (BA-03) ...... 54 Jiang C. (BF-08) ...... 66 Joshi P.C. (ET-05) ...... 188 Kang H. (CV-03) ...... 120 Jana S. (CU-09) ...... 118 Jiang C. (EQ-14) ...... 182 Joshi P.C. (ET-16) ...... 189 Kang J. (FS-12) ...... 221 Janantha P. (GC-01) ...... 235 Jiang F. (GH-06) ...... 247 Joumard I. (CD-07) ...... 96 Kang S.H. (DC-07) ...... 129 Jander A. (AW-02) ...... 50 Jiang H. (EH-03) ...... 176 Ju G. (BT-08) ...... 82 Kang W. (GT-14) ...... 259 Jander A. (AW-03) ...... 50 Jiang J. (CW-09) ...... 122 Juang J. (EE-06) ...... 170 Kansakar S. (BH-07) ...... 71 Jander A. (GR-04) ...... 254 Jiang J. (DR-13) ...... 149 Jué E. (AU-08) ...... 47 Kanthasamy A.G. (FH-12) ...... 212 Janesky J. (BA-01) ...... 54 Jiang J. (DV-02) ...... 156 Jué E. (DB-05) ...... 126 Kapaklis V. (AF-07) ...... 28 Jang G. (AW-04) ...... 51 Jiang J. (EF-09) ...... 172 Jué E. (DB-07) ...... 126 Kapaklis V. (GE-06) ...... 241 Jang G. (FH-06) ...... 211 Jiang J. (EW-05) ...... 194 Jué E. (DU-06) ...... 154 Kapteyn H.C. (EU-08) ...... 190 Jang J. (EW-06) ...... 195 Jiang J. (FP-14) ...... 214 Jun H. (DR-11) ...... 148 Kapteyn H.C. (FB-05) ...... 199 Jang M. (DB-10) ...... 127 Jiang J. (HG-05) ...... 277 Jun M. (DS-08) ...... 150 Kar N. (GG-10) ...... 246 Jang S. (AR-13) ...... 41 Jiang L. (DS-02) ...... 149 Jun S.C. (FH-13) ...... 212 Karapetrov G. (DU-13) ...... 155 Jang T. (EV-06) ...... 192 Jiang L. (ER-12) ...... 184 Jung Gu L. (EV-04) ...... 192 Karapetrova E. (DQ-12) ...... 146 Jang T. (GF-06) ...... 243 Jiang L. (EV-01) ...... 192 Jung H. (AC-12) ...... 22 Karczewski J. (AW-15) ...... 52 Janickovic D. (CG-01) ...... 101 Jiang S. (BR-14) ...... 78 Jung J. (AP-17) ...... 37 Kardasz B. (BC-02) ...... 58 Jansen R. (AB-03) ...... 18 Jiang S. (ET-02) ...... 187 Jung J. (GU-06) ...... 260 Kardasz B. (GC-08) ...... 236 Jansen R. (HB-05) ...... 266 Jiang W. (CW-02) ...... 121 Jung T. (CR-02) ...... 111 Karis O. (CU-09) ...... 118 Janssen P. (EB-07) ...... 164 Jiang W. (EP-14) ...... 180 Jungfleisch B. (EC-11) ...... 166 Karis O. (DC-02) ...... 128 Jantz M. (BC-02) ...... 58 Jiang X. (GC-06) ...... 236 Jungfleisch M.B. (EC-02) ...... 165 Karis O. (HC-02) ...... 267 Jara A.A. (BD-10) ...... 61 Jiang X. (GF-09) ...... 243 Jungwirth T. (DP-07) ...... 143 Karna S. (HD-08) ...... 271 Jardiel T. (GS-12) ...... 257 Jiang Y. (BE-06) ...... 63 Jungwirth T. (EB-01) ...... 163 Karpenkov D.Y. (EF-03) ...... 171 Jarrier R. (CE-03) ...... 97 Jiang Y. (FV-07) ...... 227 Juraszek J. (AE-02) ...... 25 Kasai N. (BB-11) ...... 57 Javed K. (DV-02) ...... 156 Jiang Y. (FV-10) ...... 227 Kasai N. (BS-02) ...... 79 Jayaraman R. (EU-11) ...... 191 Jiles D.C. (AP-12) ...... 36 - K - Kasai N. (CD-06) ...... 96 Jayaraman T. (HE-09) ...... 273 Jiles D.C. (AW-14) ...... 52 Kasai S. (CP-06) ...... 107 Jayathilaka P. (AD-09) ...... 24 Jiles D.C. (CF-01) ...... 99 Kabanov Y. (GE-07) ...... 241 Kasai S. (DH-10) ...... 141 Je S. (AU-05) ...... 46 Jiles D.C. (CH-09) ...... 105 Kabatek M. (BC-02) ...... 58 Kashiwagi S. (CT-20) ...... 117 Je S. (DB-06) ...... 126 Jiles D.C. (CQ-15) ...... 110 Kabatek M. (CX-12) ...... 124 Kashyap A. (AF-05) ...... 28 Jeen H. (BE-02) ...... 62 Jiles D.C. (FH-12) ...... 212 Kabos P. (CP-11) ...... 108 Kashyap A. (DS-05) ...... 150 Jekal S. (GQ-13) ...... 253 Jiles D.C. (FQ-06) ...... 216 Kacenka M. (DE-10) ...... 134 Kashyap A. (DS-07) ...... 150 Jen S.U. (FS-02) ...... 220 Jiles D.C. (GR-09) ...... 254 Kadam R.H. (DV-11) ...... 157 Kashyap A. (FD-06) ...... 203 Jenkins C. (AD-02) ...... 23 Jiles D.C. (HD-11) ...... 271 Kado Y. (FG-05) ...... 209 Kashyap A. (FV-12) ...... 228 Jenkins C.A. (BE-12) ...... 64 Jiménez E. (HC-01) ...... 267 Kadonosawa K. (AV-01) ...... 48 Kasperchik V. (AW-03) ...... 50 Jenkins C.A. (EQ-10) ...... 182 Jimenez-Villacorta F. (DV-14) . . . . .157 Kadonosawa K. (HF-04) ...... 274 Kaster B. (EU-02) ...... 189 Jenkins C.A. (HH-05) ...... 279 Jimenez-Villacorta F. (ED-12) . . . . .169 Kaesewurm B. (EF-03) ...... 171 Kataoka H. (DT-14) ...... 153 Jeon K. (AB-03) ...... 18 Jiménez-Villacorta F. (ED-13) . . . . .169 Kahng B. (FU-15) ...... 226 Katayama R. (CT-03) ...... 115 Jeon S. (AW-04) ...... 51 Jiménez-Villacorta F. (EF-06) ...... 172 Kaido C. (BQ-02) ...... 75 Katine J.A. (CB-09) ...... 92 Jeong D. (DB-10) ...... 127 Jiménez-Villada A. (BR-05) ...... 77 Kaiju H. (FP-05) ...... 213 Katine J.A. (CU-15) ...... 119 Jeong I. (EG-06) ...... 174 Jin C.L. (EX-07) ...... 197 Kainuma R. (BS-13) ...... 80 Katine J.A. (DP-15) ...... 144 Jeong I. (EG-10) ...... 174 Jin L. (AT-05) ...... 44 Kainuma R. (FX-07) ...... 230 Katiyar R.S. (CQ-16) ...... 111 Jeong J. (BS-04) ...... 79 Jin L. (AT-16) ...... 46 Kaiser A.M. (FC-02) ...... 200 Katiyar R.S. (FS-04) ...... 220 Jeong J. (BS-07) ...... 80 Jin L. (BP-05) ...... 73 Kaiser M. (DG-12) ...... 139 Katmis F. (AB-02) ...... 18 Jeong J. (CP-16) ...... 108 Jin L. (BU-07) ...... 84 Kajiwara Y. (BP-11) ...... 74 Kato A. (AV-12) ...... 50 Jeong J. (HH-05) ...... 279 Jin L. (EP-06) ...... 179 Kákay A. (DX-11) ...... 161 Kato A. (CG-02) ...... 102 Jeong S. (AX-10) ...... 53 Jin S. (DF-04) ...... 136 Kakazei G.N. (AC-06) ...... 21 Kato A. (FF-04) ...... 206 Jeong S. (AX-11) ...... 53 Jin T. (AP-08) ...... 36 Kakazei G.N. (AP-03) ...... 35 Kato A. (FF-05) ...... 207 Jeong S. (DU-11) ...... 155 Jin T. (DT-09) ...... 152 Kalache A. (AB-11) ...... 20 Kato A. (FF-07) ...... 207 Jerry M.J. (FA-03) ...... 198 Jin X. (DH-07) ...... 141 Kalarickal S. (FE-07) ...... 205 Kato A. (FF-12) ...... 208 Jessen B.S. (ET-17) ...... 189 Jin Y. (CV-12) ...... 120 Kalinikos B.A. (FS-03) ...... 220 Kato H. (AV-05) ...... 49 Jesus C.R. (DQ-10) ...... 146 Jin Y. (DF-11) ...... 137 Kalitsov A. (GC-07) ...... 236 Kato T. (BT-04) ...... 81 304 PROGRAM PROGRAM 305

Kato T. (CT-12) ...... 116 Khan F. (DF-07) ...... 136 Kim H. (ER-05) ...... 183 Kirby B.J. (BE-12) ...... 64 Kato T. (DP-01) ...... 142 Khan M. (FB-11) ...... 200 Kim H. (ER-08) ...... 183 Kirby B.J. (CC-09) ...... 94 Kato T. (FP-07) ...... 213 Khan M.A. (FR-14) ...... 219 Kim H. (EV-06) ...... 192 Kirby B.J. (FT-05) ...... 222 Katsnelson M.I. (DE-04) ...... 133 Khan O.U. (BX-10) ...... 89 Kim H. (GF-06) ...... 243 Kirby H. (AD-09) ...... 24 Katsumata K. (DW-08) ...... 159 Kharel P. (AT-13) ...... 45 Kim I. (CV-01) ...... 119 Kirichenko A. (DP-03) ...... 143 Kaur D. (GS-10) ...... 256 Kharel P. (DD-10) ...... 132 Kim J. (BB-13) ...... 57 Kirihara A. (EC-06) ...... 166 Kaur M. (CW-02) ...... 121 Khashab N. (BH-04) ...... 71 Kim J. (CB-02) ...... 91 Kirilyuk A. (DE-04) ...... 133 Kaur M. (CW-07) ...... 122 Khizroev S. (DP-04) ...... 143 Kim J. (DB-08) ...... 126 Kirilyuk A. (FB-04) ...... 199 Kaur M. (EP-14) ...... 180 Kho Z. (EH-06) ...... 176 Kim J. (DB-13) ...... 127 Kirino F. (AP-02) ...... 35 Kavaldzhiev M. (AS-08) ...... 42 Khor A. (AC-02) ...... 20 Kim J. (DR-10) ...... 148 Kirino F. (DV-08) ...... 157 Kawaguchi H. (DP-05) ...... 143 Khovaylo V. (FX-07) ...... 230 Kim J. (DU-06) ...... 154 Kirschner J. (DE-08) ...... 134 Kawahara K. (DP-02) ...... 143 Khovaylo V.V. (BF-12) ...... 67 Kim J. (FB-03) ...... 198 Kishi T. (CP-05) ...... 107 Kawahara T. (BT-17) ...... 83 Khurshid H. (AQ-09) ...... 38 Kim J. (FC-04) ...... 201 Kishimoto H. (CG-02) ...... 102 Kawakami R. (BC-12) ...... 59 Khurshid H. (EE-05) ...... 170 Kim J. (FE-02) ...... 204 Kishimura Y. (FP-04) ...... 213 Kawakami R.K. (CD-12) ...... 96 Khurshid H. (EP-04) ...... 179 Kim J. (FS-12) ...... 221 Kishine J. (GD-11) ...... 239 Kawami T. (FX-03) ...... 230 Khvalkovskiy A. (DA-03) ...... 125 Kim J. (FU-10) ...... 225 Kita E. (AF-03) ...... 28 Kawamoto K. (FX-01) ...... 230 Khvalkovskiy A. (GC-09) ...... 236 Kim J. (HB-06) ...... 266 Kita E. (AF-13) ...... 29 Kawamura Y. (AQ-12) ...... 38 Khvalkovskiy A. (GT-11) ...... 258 Kim J. (HH-01) ...... 278 Kita E. (DU-14) ...... 155 Kawana D. (FF-12) ...... 208 Khvalkovskiy A.V. (DC-08) ...... 129 Kim K. (AX-02) ...... 52 Kita E. (FP-07) ...... 213 Kawano K. (GG-05) ...... 245 Khymyn R. (FG-07) ...... 209 Kim K. (BB-11) ...... 57 Kitagawa E. (CP-05) ...... 107 Kawazoe Y. (BR-15) ...... 78 Kief M. (FT-05) ...... 222 Kim K. (BD-13) ...... 62 Kitakami O. (AV-01) ...... 48 Kaya D. (AD-09) ...... 24 Kiermaier J. (BB-14) ...... 57 Kim K. (CB-13) ...... 92 Kitakami O. (BT-05) ...... 81 Kazakova O. (DX-06) ...... 160 Kiermaier J. (BQ-12) ...... 76 Kim K. (DP-06) ...... 143 Kitakami O. (BT-14) ...... 82 Kazakova O. (EA-01) ...... 161 Kiermaier J. (HG-06) ...... 277 Kim K. (DR-10) ...... 148 Kitakami O. (CT-14) ...... 116 Kazakova O. (FU-05) ...... 224 Kikuchi D. (BP-11) ...... 74 Kim K. (EU-01) ...... 189 Kitakami O. (DT-14) ...... 153 Kazakova O. (GB-10) ...... 234 Kikuchi H. (AR-06) ...... 40 Kim K. (FA-04) ...... 198 Kitakami O. (DT-15) ...... 153 Kazuhiro H. (HF-13) ...... 276 Kikuchi H. (DT-14) ...... 153 Kim K. (FH-13) ...... 212 Kitakami O. (FE-06) ...... 205 Ke L. (AF-04) ...... 28 Kikuchi H. (FP-04) ...... 213 Kim K. (FU-07) ...... 224 Kitakami O. (HF-04) ...... 274 Ke L. (DF-12) ...... 137 Kikuchi N. (AV-01) ...... 48 Kim K. (GS-05) ...... 256 Kitching J. (YA-01) ...... 90 Ke W. (AQ-13) ...... 39 Kikuchi N. (BT-05) ...... 81 Kim K. (HG-04) ...... 276 Kiwa T. (GR-06) ...... 254 Keating A. (ET-04) ...... 187 Kikuchi N. (BT-14) ...... 82 Kim M. (CQ-08) ...... 110 Kjaer D. (BS-14) ...... 81 Keatley P.S. (DB-12) ...... 127 Kikuchi N. (CT-14) ...... 116 Kim S. (AC-12) ...... 22 Kjær D. (ET-17) ...... 189 Keatley P.S. (EH-10) ...... 177 Kikuchi N. (DT-14) ...... 153 Kim S. (AS-02) ...... 42 Klaeui M. (DB-13) ...... 127 Keatley P.S. (FT-06) ...... 222 Kikuchi N. (DT-15) ...... 153 Kim S. (AS-07) ...... 42 Klaeui M. (EC-02) ...... 165 Keavney D. (BD-06) ...... 61 Kikuchi N. (FE-06) ...... 205 Kim S. (BG-05) ...... 68 Kläui M. (BG-02) ...... 68 Keavney D. (DQ-12) ...... 146 Kikuchi N. (HF-04) ...... 274 Kim S. (BP-08) ...... 73 Kläui M. (CF-09) ...... 100 Keavney D.J. (AH-03) ...... 33 Kilaru R. (BA-02) ...... 54 Kim S. (DR-01) ...... 147 Kläui M. (CT-15) ...... 116 Keavney D.J. (FC-04) ...... 201 Kilaru R. (GC-06) ...... 236 Kim S. (DR-15) ...... 149 Kläui M. (FS-01) ...... 219 Keavney D.J. (GP-10) ...... 250 Kim B. (AX-10) ...... 53 Kim S. (EU-16) ...... 191 Klaui M. (FU-10) ...... 225 Keavney D.J. (GR-01) ...... 253 Kim B. (AX-11) ...... 53 Kim S. (EW-10) ...... 195 Kleibert A. (DD-01) ...... 130 Keavney D.J. (HB-06) ...... 266 Kim B. (DU-11) ...... 155 Kim S. (GE-08) ...... 241 Klein J. (FU-08) ...... 225 Keenan K. (FH-11) ...... 212 Kim C. (AV-14) ...... 50 Kim T. (AG-05) ...... 30 Klein J. (GT-14) ...... 259 Kehlberger A. (EC-02) ...... 165 Kim C. (CX-02) ...... 123 Kim T. (CD-04) ...... 95 Klein O. (BC-09) ...... 59 Keller M. (DA-02) ...... 124 Kim C. (CX-03) ...... 123 Kim T. (EV-06) ...... 192 Klein O. (EH-08) ...... 177 Kelley C.S. (BE-11) ...... 64 Kim C. (CX-05) ...... 123 Kim T. (GF-06) ...... 243 Klein O. (EH-09) ...... 177 Kelley C.S. (HC-12) ...... 269 Kim C. (DQ-14) ...... 147 Kim W. (AX-11) ...... 53 Klein O. (GP-05) ...... 249 Kennedy R.J. (EQ-08) ...... 181 Kim C. (EQ-01) ...... 180 Kim W. (BS-07) ...... 80 Klein T. (DQ-15) ...... 147 Kennedy S. (CF-10) ...... 100 Kim C. (FE-13) ...... 206 Kim W. (DU-11) ...... 155 Klein T. (GR-14) ...... 255 Kennedy S. (DD-13) ...... 132 Kim C. (GU-06) ...... 260 Kim Y. (BS-07) ...... 80 Klemm A. (BC-11) ...... 59 Kennedy S. (EF-02) ...... 171 Kim D. (AE-08) ...... 26 Kim Y. (DG-09) ...... 139 Klemm A. (DH-13) ...... 142 Kennedy S.J. (CQ-13) ...... 110 Kim D. (AR-03) ...... 39 Kim Y. (DW-06) ...... 158 Klemm A. (GT-13) ...... 259 Kennedy S.J. (ED-10) ...... 168 Kim D. (AU-05) ...... 46 Kim Y. (EW-06) ...... 195 Klemmer T.J. (AF-01) ...... 27 Kennedy S.J. (GQ-03) ...... 252 Kim D. (BU-14) ...... 85 Kimata M. (GC-05) ...... 236 Klos J.W. (AC-10) ...... 22 Kent A.D. (AH-04) ...... 33 Kim D. (CP-16) ...... 108 Kimel A. (FB-04) ...... 199 Klos J.W. (BU-04) ...... 83 Kent A.D. (BU-06) ...... 84 Kim D. (DB-06) ...... 126 Kimerling L.C. (GD-05) ...... 238 Klos J.W. (BU-08) ...... 84 Kent A.D. (CB-03) ...... 91 Kim D. (DE-09) ...... 134 Kimura A. (AB-10) ...... 19 Knizek K. (AQ-03) ...... 37 Kent A.D. (CB-12) ...... 92 Kim D. (EC-02) ...... 165 Kimura T. (BG-07) ...... 69 Knizek K. (CQ-11) ...... 110 Kent A.D. (DP-03) ...... 143 Kim D. (EQ-09) ...... 181 Kimura T. (EC-01) ...... 165 Knowles E.S. (FD-08) ...... 203 Kent A.D. (DP-15) ...... 144 Kim D. (FU-09) ...... 225 Kimura T. (EW-08) ...... 195 Knut R. (DC-02) ...... 128 Kent A.D. (GC-08) ...... 236 Kim D. (FU-15) ...... 226 Kimura Y. (AV-02) ...... 48 Knut R. (HC-02) ...... 267 Kernion S.J. (CG-03) ...... 102 Kim D. (FU-16) ...... 226 Kinane C. (AB-01) ...... 18 Kobayashi K. (FU-07) ...... 224 Keshavarz S. (ED-09) ...... 168 Kim D. (FW-05) ...... 228 Kinane C.J. (AG-07) ...... 31 Kobayashi N. (EQ-13) ...... 182 Ketabi S. (ED-06) ...... 168 Kim D. (GP-09) ...... 250 Kino H. (BF-02) ...... 65 Kobayashi Y. (AQ-12) ...... 38 Ketterson J. (AQ-04) ...... 38 Kim D.H. (FS-12) ...... 221 Kinoshita K. (BS-02) ...... 79 Kobs A. (DG-07) ...... 139 Ketterson J. (BC-04) ...... 58 Kim E. (GU-14) ...... 261 Kinoshita K. (CD-05) ...... 95 Kobs A. (ES-14) ...... 186 Ketterson J.B. (CB-08) ...... 92 Kim G. (EU-02) ...... 189 Kinoshita K. (CD-06) ...... 96 Kockelmann W.A. (EF-07) ...... 172 Ketterson J.B. (DD-06) ...... 131 Kim H. (AR-03) ...... 39 Kinoshita Y. (FC-08) ...... 201 Koda T. (BP-13) ...... 74 Ketterson J.B. (ET-14) ...... 189 Kim H. (AT-07) ...... 45 Kinoshita Y. (FS-15) ...... 221 Koenraad P.M. (GH-13) ...... 248 Kevan S. (BE-08) ...... 63 Kim H. (AV-14) ...... 50 Kioussis N. (ES-06) ...... 185 Koganezawa T. (AG-04) ...... 30 Keylin V. (CG-03) ...... 102 Kim H. (AX-02) ...... 52 Kioussis N. (GC-07) ...... 236 Kohlbrecher J. (BF-06) ...... 66 Khalili Amiri P. (EH-03) ...... 176 Kim H. (DQ-14) ...... 147 Kirby B. (AF-10) ...... 29 Kohlbrecher J. (FF-04) ...... 206 Khalili Amiri P. (ES-06) ...... 185 Kim H. (EG-10) ...... 174 Kirby B. (DQ-12) ...... 146 Kohmoto S. (EC-06) ...... 166 306 PROGRAM PROGRAM 307

Kohn A. (AD-12) ...... 24 Kou Z. (DE-11) ...... 135 Kuanr A.V. (FP-01) ...... 212 Kuroiwa Y. (AX-11) ...... 53 Kohn A. (FX-09) ...... 231 Koubaa M. (CF-15) ...... 101 Kuanr B.K. (CW-10) ...... 122 Kurt H. (DH-01) ...... 140 Kohno H. (FU-07) ...... 224 Kouh T. (DQ-14) ...... 147 Kuanr B.K. (DR-07) ...... 148 Kusaka T. (GR-06) ...... 254 Koide T. (DT-07) ...... 152 Kousaka Y. (GD-11) ...... 239 Kuanr B.K. (ET-06) ...... 188 Kuschel T. (AT-06) ...... 44 Koike H. (DC-01) ...... 128 Kovac J. (CG-01) ...... 101 Kuanr B.K. (FG-09) ...... 209 Kuschel T. (GR-02) ...... 254 Koike H. (HB-02) ...... 265 Kovac J. (EF-04) ...... 171 Kuanr B.K. (FP-01) ...... 212 Kuteifan M. (DB-04) ...... 126 Koike K. (AF-13) ...... 29 Kovács A. (AD-12) ...... 24 Kübel C. (BF-06) ...... 66 Kutzke D.T. (AU-15) ...... 48 Koike K. (AV-05) ...... 49 Kovacs A. (CT-08) ...... 116 Kubic R.C. (DF-06) ...... 136 Kuzmin M. (DF-08) ...... 136 Koiwa K. (GR-10) ...... 255 Kovács A. (FX-09) ...... 231 Kubota H. (BG-04) ...... 68 Kuzmin M.D. (EF-03) ...... 171 Kojima H. (ES-02) ...... 185 Kovintavewat P. (CT-09) ...... 116 Kubota H. (BS-12) ...... 80 Kuzovnikov A.A. (FR-10) ...... 218 Kojima T. (AG-04) ...... 30 Kovintavewat P. (GW-02) ...... 263 Kubota H. (CB-01) ...... 91 Kuzovnikova L.A. (FR-10) ...... 218 Kojima T. (CQ-05) ...... 109 Kowalska E. (CU-07) ...... 118 Kubota H. (CB-11) ...... 92 Kwo R. (HB-07) ...... 266 Kojima T. (CU-11) ...... 118 Koyama T. (BB-11) ...... 57 Kubota H. (CP-01) ...... 106 Kwon B. (HE-01) ...... 272 Kolhatkar A. (AS-01) ...... 41 Koyama T. (EU-01) ...... 189 Kubota H. (CU-05) ...... 118 Kwon H. (EV-04) ...... 192 Kolmychek I. (EE-09) ...... 170 Koyama T. (FU-07) ...... 224 Kubota H. (DA-03) ...... 125 Kwon J. (BW-03) ...... 87 Koltsova I. (FW-01) ...... 228 Kozhanov A. (BW-10) ...... 88 Kubota H. (DC-03) ...... 128 Kwon J. (CR-15) ...... 113 Komineas S. (BG-08) ...... 69 Kozhanov A. (CU-16) ...... 119 Kubota H. (DC-06) ...... 129 Kwon J. (EP-01) ...... 178 Komissinskiy P. (AE-12) ...... 27 Krafft C. (BT-10) ...... 82 Kubota H. (EH-12) ...... 177 Kwon J. (FP-12) ...... 214 Komiyama K. (BT-05) ...... 81 Krafft C. (EG-08) ...... 174 Kubota H. (EH-13) ...... 178 Kwon O. (GQ-13) ...... 253 Komogortsev S.V. (DV-03) ...... 156 Krafft C. (EG-09) ...... 174 Kubota H. (FU-14) ...... 225 Kypris O. (AW-14) ...... 52 Komogortsev S.V. (FR-12) ...... 218 Krafft C. (GD-03) ...... 238 Kubota H. (GU-04) ...... 259 Kypris O. (CH-09) ...... 105 Kondo K. (FP-05) ...... 213 Kramer M. (DF-02) ...... 135 Kubota H. (GU-13) ...... 261 Kondo K. (GU-15) ...... 261 Kramer M. (DF-12) ...... 137 Kubota H. (HA-05) ...... 265 - L - Kondo Y. (CT-06) ...... 115 Kramer M.J. (AF-10) ...... 29 Kubota K. (DR-12) ...... 148 Kondo Y. (EU-04) ...... 190 Kramer M.J. (GF-02) ...... 242 Kubota T. (AB-04) ...... 19 La Corte A. (BX-04) ...... 89 Kondou K. (CP-06) ...... 107 Kramer M.J. (GF-03) ...... 242 Kubota T. (AC-11) ...... 22 La-O-Vorakiat C. (EU-08) ...... 190 Kondou K. (DH-10) ...... 141 Krammer M.J. (DF-14) ...... 137 Kubota T. (AP-06) ...... 35 La-O-Vorakiat C. (FB-05) ...... 199 Kong G. (CT-07) ...... 115 Krause S. (FD-05) ...... 203 Kubota T. (CA-03) ...... 90 Labak A. (GG-10) ...... 246 Kong J. (EH-06) ...... 176 Krause S. (GB-08) ...... 234 Kubota T. (CU-06) ...... 118 Labarta A. (DE-01) ...... 133 Konoto M. (BS-12) ...... 80 Krause S. (GC-13) ...... 237 Kubota T. (GB-13) ...... 234 Labarta A. (EA-02) ...... 162 Konoto M. (CU-05) ...... 118 Krawczyk M. (AC-10) ...... 22 Kubota Y. (BS-08) ...... 80 Lacerda S. (EW-11) ...... 195 Konoto M. (DC-03) ...... 128 Krawczyk M. (BU-04) ...... 83 Kucera M. (AT-07) ...... 45 Lacoste B. (DP-14) ...... 144 Konoto M. (HA-05) ...... 265 Krawczyk M. (BU-08) ...... 84 Kuch W. (GE-12) ...... 242 Lacour D. (AG-01) ...... 30 Koo C.Y. (BR-06) ...... 77 Krayer L.J. (FT-05) ...... 222 Kudo K. (FT-01) ...... 221 Lacour D. (GB-15) ...... 235 Koo D. (CV-06) ...... 120 Kremer R.K. (FD-11) ...... 204 Kudo K. (FT-02) ...... 222 Laczkowski P. (AU-10) ...... 47 Koo H. (AB-13) ...... 20 Krempasky J. (ED-03) ...... 167 Kudrnovsky J. (EB-01) ...... 163 Laczkowski P. (BB-07) ...... 56 Koo J. (AG-03) ...... 30 Krishna V. (BT-06) ...... 82 Kuepferling M. (GQ-09) ...... 252 Laczkowski P. (BP-14) ...... 74 Koo M. (AR-13) ...... 41 Krishnan K.M. (AD-03) ...... 23 Kugler Z. (GR-02) ...... 254 Laczkowski P. (BU-09) ...... 84 Kooi B. (GG-02) ...... 245 Krishnan K.M. (FH-08) ...... 211 Kuhlmann N. (BP-07) ...... 73 Lahtinen T. (HA-03) ...... 264 Koomson V. (FG-08) ...... 209 Krishnan K.M. (HE-01) ...... 272 Kuhns P.L. (CS-03) ...... 113 Lai C. (AF-01) ...... 27 Koopmans B. (BB-03) ...... 55 Krishnan K.M. (HG-07) ...... 277 Kuiper K. (FB-02) ...... 198 Lai C. (AG-10) ...... 31 Koopmans B. (BB-06) ...... 56 Kristan P. (CX-04) ...... 123 Kukreja R. (DU-01) ...... 153 Lai C. (AP-05) ...... 35 Koopmans B. (DB-08) ...... 126 Krivorotov I. (DH-14) ...... 142 Kukreja R. (HH-05) ...... 279 Lai C. (CC-05) ...... 93 Koopmans B. (EB-07) ...... 164 Krivorotov I. (EC-13) ...... 166 Kukusta D. (AF-04) ...... 28 Lai C. (CW-08) ...... 122 Koopmans B. (FB-02) ...... 198 Krivorotov I. (GD-04) ...... 238 Kula W. (BA-02) ...... 54 Lai C. (DT-05) ...... 152 Korenev S.V. (DV-03) ...... 156 Krivorotov I.N. (BD-10) ...... 61 Kula W. (GC-06) ...... 236 Lai C. (EE-06) ...... 170 Körner M. (BG-01) ...... 67 Krivorotov I.N. (CB-09) ...... 92 Kumagai S. (DT-01) ...... 151 Lai C. (FH-09) ...... 211 Kortan V.R. (GH-13) ...... 248 Krivorotov I.N. (CU-15) ...... 119 Kumagai S. (DT-02) ...... 151 Lai C. (GG-10) ...... 246 Kortright J. (BR-10) ...... 78 Krivorotov I.N. (DH-05) ...... 140 Kumai R. (BF-09) ...... 66 Lai C. (HF-01) ...... 274 Kosel J. (BH-04) ...... 71 Krivorotov I.N. (GB-04) ...... 233 Kumai R. (FF-05) ...... 207 Lai M. (AW-06) ...... 51 Kosel J. (BH-05) ...... 71 Krivorotov I.N. (GP-17) ...... 251 Kumar A. (FX-06) ...... 230 Lai M. (ET-04) ...... 187 Kosel J. (BH-09) ...... 71 Kronast F. (CF-09) ...... 100 Kumar D. (AC-10) ...... 22 Lai M. (EW-07) ...... 195 Kosel J. (FH-03) ...... 211 Kronast F. (FC-02) ...... 200 Kumar D. (BU-04) ...... 83 Lai P. (DX-07) ...... 160 Kosel J. (GG-03) ...... 245 Kronast F. (FS-01) ...... 219 Kumar D. (GS-09) ...... 256 Lai S. (AG-10) ...... 31 Kosel J. (HG-02) ...... 276 Kronast F. (GE-06) ...... 241 Kumar M. (AU-02) ...... 46 Lambert C. (GD-01) ...... 237 Kostylev M. (AC-02) ...... 20 Kronmüller H. (DF-05) ...... 136 Kumar P. (FD-06) ...... 203 Lammert P.E. (DD-03) ...... 131 Kostylev M. (BU-01) ...... 83 Krounbi M. (DC-08) ...... 129 Kumar P. (FV-12) ...... 228 Lampen P. (EF-01) ...... 171 Kostylev M. (CH-02) ...... 104 Krounbi M. (GC-09) ...... 236 Kumar P.V. (CQ-15) ...... 110 Lampen P.J. (AQ-02) ...... 37 Kostylev M. (CP-09) ...... 107 Krug I. (FC-12) ...... 202 Kummer K. (HH-02) ...... 278 Lampen P.J. (GD-07) ...... 238 Kostylev M. (ET-04) ...... 187 Krüger B. (BG-02) ...... 68 Kunz A. (AU-15) ...... 48 Lamperti A. (AG-12) ...... 32 Kostylev M. (GE-04) ...... 240 Kruglyak V.V. (AC-05) ...... 21 Kuo C. (DU-15) ...... 155 Lamperti A. (BE-13) ...... 64 Kosuke M. (GH-02) ...... 246 Krycka K.L. (EE-01) ...... 169 Kuo H. (EE-06) ...... 170 Lamperti A. (BS-16) ...... 81 Kota Y. (EB-09) ...... 164 Kryder M. (GU-06) ...... 260 Kuo P. (DT-06) ...... 152 Lamperti A. (FS-09) ...... 220 Kota Y. (HH-06) ...... 279 Kryder M.H. (FE-10) ...... 205 Kuo P.C. (DT-03) ...... 151 Lamperti A. (FU-10) ...... 225 Kotagiri G. (CG-07) ...... 102 Kryder M.H. (FE-13) ...... 206 Kuo T. (AP-15) ...... 37 Lamperti A. (HC-06) ...... 268 Kotani M. (AW-11) ...... 51 Kryutyanskiy V. (EE-09) ...... 170 Kuo W. (EE-06) ...... 170 Lan T. (AW-06) ...... 51 Kotani Y. (FF-02) ...... 206 Krzysteczko P. (DU-10) ...... 154 Kura H. (BW-02) ...... 87 Lan T. (EP-08) ...... 179 Koten M. (FV-12) ...... 228 Krzysteczko P. (DX-06) ...... 160 Kura H. (HD-09) ...... 271 Landau D.P. (EU-05) ...... 190 Kotov L.N. (BW-06) ...... 88 Krzysteczko P. (FU-05) ...... 224 Kurahashi M. (AG-02) ...... 30 Landeros P. (DB-01) ...... 125 Kotsugi M. (AG-04) ...... 30 Kuang H. (EQ-06) ...... 181 Kurebayashi H. (DP-07) ...... 143 Lang G.S. (GD-03) ...... 238 Kou B. (CV-10) ...... 120 Kuanr A.V. (CW-10) ...... 122 Kurian J. (AF-09) ...... 28 Lang J. (HH-01) ...... 278 Kou B. (CV-12) ...... 120 Kuanr A.V. (FG-09) ...... 209 Kurlyandskaya G. (GG-02) ...... 245 Lang J.C. (CQ-09) ...... 110 308 PROGRAM PROGRAM 309

Lang M. (EB-02) ...... 163 Lee C. (DU-15) ...... 155 Lee S. (BW-03) ...... 87 Lewis L.H. (DV-14) ...... 157 Langouche L. (GH-11) ...... 248 Lee C. (EG-04) ...... 174 Lee S. (CB-08) ...... 92 Lewis L.H. (ED-12) ...... 169 Langridge S. (AB-01) ...... 18 Lee C. (EG-11) ...... 175 Lee S. (CP-15) ...... 108 Lewis L.H. (ED-13) ...... 169 Langridge S. (AG-07) ...... 31 Lee C. (FW-06) ...... 229 Lee S. (CV-16) ...... 121 Lewis L.H. (EF-06) ...... 172 Langridge S. (BD-05) ...... 60 Lee D. (AV-06) ...... 49 Lee S. (DB-10) ...... 127 Lewis L.H. (ET-15) ...... 189 Langridge S. (CC-10) ...... 94 Lee D. (EV-02) ...... 192 Lee S. (DU-11) ...... 155 Lewis L.H. (FV-05) ...... 227 Langridge S. (DD-05) ...... 131 Lee D. (EV-05) ...... 192 Lee S. (EG-06) ...... 174 Li B. (GG-03) ...... 245 Lao B. (AP-17) ...... 37 Lee D. (EV-10) ...... 193 Lee S. (EP-01) ...... 178 Li B. (HG-02) ...... 276 Lao Y. (CP-09) ...... 107 Lee D. (EV-12) ...... 193 Lee S. (EV-06) ...... 192 Li C. (EV-03) ...... 192 Lapa P.N. (AD-09) ...... 24 Lee D. (GF-08) ...... 243 Lee S. (FW-05) ...... 228 Li C.H. (FD-08) ...... 203 Lara Pérez E.S. (FQ-02) ...... 215 Lee D. (GU-14) ...... 261 Lee S. (GE-08) ...... 241 Li D. (BQ-16) ...... 76 Lardé R. (FC-07) ...... 201 Lee E. (FS-12) ...... 221 Lee S. (GF-06) ...... 243 Li D. (CT-10) ...... 116 Lari L. (EE-07) ...... 170 Lee H. (CD-04) ...... 95 Lee S. (GP-09) ...... 250 Li D. (CW-09) ...... 122 Lari L. (GH-02) ...... 246 Lee H. (CV-08) ...... 120 Lee S. (GU-14) ...... 261 Li D. (DR-13) ...... 149 Lari L. (GH-07) ...... 247 Lee H. (CV-16) ...... 121 Lee S. (HB-07) ...... 266 Li D. (EW-05) ...... 194 Lascialfari A. (AQ-10) ...... 38 Lee H. (DH-11) ...... 141 Lee T. (CC-06) ...... 93 Li E. (BH-05) ...... 71 Lasek M.P. (BW-06) ...... 88 Lee H. (DP-06) ...... 143 Lee T. (GU-11) ...... 260 Li F. (BH-09) ...... 71 Lau J.W. (BS-06) ...... 79 Lee H. (DV-01) ...... 156 Lee W. (DU-07) ...... 154 Li G. (DF-02) ...... 135 Lau J.W. (FE-13) ...... 206 Lee H. (ED-09) ...... 168 Lee W. (FG-13) ...... 210 Li G. (GQ-01) ...... 251 Lau Y. (DH-01) ...... 140 Lee H. (EU-16) ...... 191 Lee W. (HD-03) ...... 270 Li H. (BT-08) ...... 82 Laudani A. (DH-02) ...... 140 Lee H. (FA-04) ...... 198 Lee W. (HF-07) ...... 275 Li H. (BT-09) ...... 82 Lauer G. (BA-02) ...... 54 Lee H. (FS-05) ...... 220 Lee Y. (BA-03) ...... 54 Li H. (FE-12) ...... 206 Lauer G.P. (GC-06) ...... 236 Lee H. (FW-05) ...... 228 Lee Y. (GU-12) ...... 260 Li H. (FT-12) ...... 222 Laughlin D. (BR-10) ...... 78 Lee J. (AB-13) ...... 20 Lee-Hone N.R. (CS-06) ...... 114 Li J. (AX-12) ...... 54 Laurson L. (AH-07) ...... 33 Lee J. (AR-03) ...... 39 Lefeuvre E. (HG-03) ...... 276 Li J. (BR-13) ...... 78 Lauter V. (BE-04) ...... 63 Lee J. (CC-01) ...... 93 Lefevre P. (AG-01) ...... 30 Li J. (BT-11) ...... 82 Lauter V. (BP-15) ...... 74 Lee J. (CC-02) ...... 93 LeFrançois S. (BE-11) ...... 64 Li J. (CX-01) ...... 123 Lauter V. (HC-07) ...... 268 Lee J. (CV-08) ...... 120 LeFrançois S. (HC-12) ...... 269 Li J. (CX-10) ...... 124 Laver M. (BE-04) ...... 63 Lee J. (DR-10) ...... 148 Legut D. (AT-06) ...... 44 Li J. (ED-07) ...... 168 Laviano F. (GQ-09) ...... 252 Lee J. (DW-06) ...... 158 Legut D. (ED-02) ...... 167 Li J. (EE-08) ...... 170 Lavín R. (CW-04) ...... 122 Lee J. (DW-07) ...... 159 Legut D. (FD-10) ...... 204 Li J. (EF-09) ...... 172 Lavrijsen R. (BG-02) ...... 68 Lee J. (ER-11) ...... 184 Lei G. (EG-05) ...... 174 Li J. (ER-03) ...... 183 Lavrijsen R. (CC-01) ...... 93 Lee J. (ET-14) ...... 189 Lei N. (FU-10) ...... 225 Li J. (EX-07) ...... 197 Lavrijsen R. (CC-02) ...... 93 Lee J. (EU-16) ...... 191 Leicht P. (HE-12) ...... 273 Li J. (EX-08) ...... 197 Lavrijsen R. (CC-10) ...... 94 Lee J. (FG-13) ...... 210 Leighton C. (BE-01) ...... 62 Li J. (FE-03) ...... 204 Lawes G. (FH-04) ...... 211 Lee J. (FH-06) ...... 211 Leighton C. (BE-04) ...... 63 Li L. (AW-13) ...... 52 Lazarov V. (AX-03) ...... 52 Lee J. (HD-03) ...... 270 Leighton C. (BP-15) ...... 74 Li L. (CS-07) ...... 114 Lazarov V. (EE-07) ...... 170 Lee J.H. (BB-12) ...... 57 Leighton C. (DD-03) ...... 131 Li L. (CV-09) ...... 120 Lazarov V.K. (BE-11) ...... 64 Lee J.H. (CC-10) ...... 94 Leineweber A. (DF-05) ...... 136 Li L. (ES-13) ...... 186 Lazarov V.K. (GH-02) ...... 246 Lee J.H. (ET-10) ...... 188 Leitao D.C. (AS-09) ...... 42 Li M. (AS-13) ...... 43 Lazarov V.K. (GH-07) ...... 247 Lee K. (AC-12) ...... 22 Leite D.M. (AX-08) ...... 53 Li P. (AS-05) ...... 42 Lazott R. (GQ-04) ...... 252 Lee K. (AR-13) ...... 41 Leite O. (DQ-01) ...... 145 Li P. (AS-06) ...... 42 Lazzarini L. (BS-16) ...... 81 Lee K. (AS-02) ...... 42 Leitenstorfer A. (BD-13) ...... 62 Li P. (AS-13) ...... 43 Le Breton J. (DF-10) ...... 137 Lee K. (AU-05) ...... 46 Leliaert J. (AH-07) ...... 33 Li P. (AW-10) ...... 51 Le Breton J. (FC-07) ...... 201 Lee K. (BG-11) ...... 69 Lemoine P. (DQ-11) ...... 146 Li P. (DS-09) ...... 150 Le Fevre P. (DC-04) ...... 128 Lee K. (BP-08) ...... 73 Lendinez S. (DU-12) ...... 155 Li P. (ES-10) ...... 186 Le Graet C. (AG-07) ...... 31 Lee K. (BS-04) ...... 79 Lengaigne G. (GB-15) ...... 235 Li P. (FP-06) ...... 213 Le H.H. (AU-15) ...... 48 Lee K. (CP-13) ...... 108 Leon C. (BD-08) ...... 61 Li P. (FS-06) ...... 220 Le Roy D. (AS-08) ...... 42 Lee K. (CP-15) ...... 108 Leong S. (DT-12) ...... 152 Li P. (FS-07) ...... 220 Le Roy D. (EW-14) ...... 196 Lee K. (CP-16) ...... 108 Leontsev S. (BV-02) ...... 85 Li P. (FS-10) ...... 220 Le Roy D. (FF-08) ...... 207 Lee K. (CU-01) ...... 117 Lepalovskij V.N. (GG-02) ...... 245 Li P. (GE-10) ...... 241 Le Roy D. (GF-11) ...... 244 Lee K. (DB-06) ...... 126 Lepatadu S. (CC-03) ...... 93 Li P. (GS-01) ...... 255 Le S. (BA-03) ...... 54 Lee K. (DB-10) ...... 127 Lepetit T. (HD-05) ...... 270 Li Q. (CX-01) ...... 123 Le T. (DT-13) ...... 153 Lee K. (DC-07) ...... 129 Lequeux S. (CB-01) ...... 91 Li Q. (HH-11) ...... 280 Leao L. (FA-01) ...... 197 Lee K. (DH-11) ...... 141 Lequeux S. (DB-09) ...... 127 Li Q.Z. (CR-06) ...... 111 Leao L.H. (DH-04) ...... 140 Lee K. (DP-06) ...... 143 Lesseux G.G. (AQ-15) ...... 39 Li R. (CG-13) ...... 103 Leary A. (CG-04) ...... 102 Lee K. (EU-01) ...... 189 Lesseux G.G. (CS-03) ...... 113 Li S. (BH-04) ...... 71 Leblanc M.D. (GW-03) ...... 263 Lee K. (FA-04) ...... 198 Letellier F. (DF-10) ...... 137 Li S. (BR-08) ...... 78 Lebrun R. (BG-04) ...... 68 Lee K. (FH-06) ...... 211 Letellier F. (FC-07) ...... 201 Li S. (BX-11) ...... 89 Lebrun R. (GP-05) ...... 249 Lee K. (FH-07) ...... 211 Leulmi S. (BH-02) ...... 70 Li S. (CH-11) ...... 106 Lech-Grega M. (AW-15) ...... 52 Lee K. (GP-02) ...... 249 Leulmi S. (FH-10) ...... 212 Li S. (CV-11) ...... 120 Lechevallier L. (FC-07) ...... 201 Lee M. (EV-06) ...... 192 Leung C. (AS-12) ...... 43 Li S. (CW-09) ...... 122 LeClair P. (FV-11) ...... 227 Lee M. (GF-06) ...... 243 Leung C. (AT-15) ...... 46 Li S. (DS-11) ...... 150 LeClair P.R. (ED-09) ...... 168 Lee N. (AE-01) ...... 25 Leung C. (DR-03) ...... 147 Li S. (DX-08) ...... 161 Lecoeur P. (FU-10) ...... 225 Lee N. (AE-07) ...... 26 Leung C. (EQ-12) ...... 182 Li S. (EF-09) ...... 172 Lee A. (EG-08) ...... 174 Lee N. (AG-05) ...... 30 Leutenantsmeyer J.C. (EH-07) . . . . .177 Li S. (FT-09) ...... 222 Lee A. (EG-09) ...... 174 Lee O. (FA-01) ...... 197 Lewis J. (DF-10) ...... 137 Li S. (GQ-11) ...... 253 Lee B. (EG-06) ...... 174 Lee R.T. (AS-01) ...... 41 Lewis L.H. (AF-05) ...... 28 Li S. (HC-13) ...... 269 Lee B.W. (FS-12) ...... 221 Lee S. (AU-04) ...... 46 Lewis L.H. (AG-07) ...... 31 Li T. (HE-09) ...... 273 Lee C. (AW-06) ...... 51 Lee S. (AX-10) ...... 53 Lewis L.H. (DF-01) ...... 135 Li W. (AS-05) ...... 42 Lee C. (BQ-02) ...... 75 Lee S. (AX-11) ...... 53 Lewis L.H. (DF-06) ...... 136 Li W. (AS-06) ...... 42 Lee C. (BS-05) ...... 79 Lee S. (BU-14) ...... 85 Lewis L.H. (DV-04) ...... 156 Li W. (AS-13) ...... 43 310 PROGRAM PROGRAM 311

Li W. (AW-02) ...... 50 Lim J. (CX-05) ...... 123 Liu C. (CR-09) ...... 112 Liu R. (BV-05) ...... 86 Li W. (AW-10) ...... 51 Lim J. (EQ-01) ...... 180 Liu C. (CV-02) ...... 119 Liu R. (BV-06) ...... 86 Li W. (BW-01) ...... 87 Lim P. (FC-06) ...... 201 Liu C. (CV-15) ...... 121 Liu R. (DA-04) ...... 125 Li W. (CR-03) ...... 111 Lim S. (AX-02) ...... 52 Liu D. (AT-14) ...... 45 Liu R. (GV-04) ...... 261 Li W. (CR-07) ...... 112 Lim S. (CC-06) ...... 93 Liu D. (FQ-13) ...... 216 Liu S. (DV-01) ...... 156 Li W. (CS-12) ...... 115 Lim S. (CP-11) ...... 108 Liu D. (GU-03) ...... 259 Liu S. (ER-04) ...... 183 Li W. (CV-15) ...... 121 Lim S. (EG-10) ...... 174 Liu F. (BQ-16) ...... 76 Liu T. (CX-12) ...... 124 Li W. (DS-09) ...... 150 Lim S. (GE-02) ...... 240 Liu F. (CR-12) ...... 112 Liu T. (DU-05) ...... 154 Li W. (DW-13) ...... 159 Lim W.L. (DA-04) ...... 125 Liu F. (ET-01) ...... 187 Liu T. (ED-08) ...... 168 Li W. (EE-04) ...... 169 Lin C. (DW-07) ...... 159 Liu H. (AR-14) ...... 41 Liu T. (GV-13) ...... 262 Li W. (EE-05) ...... 170 Lin C. (EG-04) ...... 174 Liu H. (AX-01) ...... 52 Liu W. (AV-09) ...... 49 Li W. (EV-02) ...... 192 Lin C. (EG-14) ...... 175 Liu H. (BA-03) ...... 54 Liu W. (BV-04) ...... 86 Li W. (EV-13) ...... 193 Lin C. (ER-11) ...... 184 Liu H. (BG-09) ...... 69 Liu W. (BV-10) ...... 86 Li W. (FS-06) ...... 220 Lin C. (HH-10) ...... 279 Liu H. (EE-06) ...... 170 Liu W. (CW-05) ...... 122 Li W. (GF-05) ...... 243 Lin E. (FT-09) ...... 222 Liu H. (FX-03) ...... 230 Liu W. (CW-09) ...... 122 Li W. (GQ-11) ...... 253 Lin E.E. (GW-01) ...... 263 Liu H. (GH-05) ...... 247 Liu W. (DR-13) ...... 149 Li W. (GV-13) ...... 262 Lin F. (CR-08) ...... 112 Liu J. (AQ-01) ...... 37 Liu W. (EV-03) ...... 192 Li W. (HE-03) ...... 272 Lin F. (CV-02) ...... 119 Liu J. (AR-09) ...... 40 Liu W. (EW-05) ...... 194 Li X. (AG-15) ...... 32 Lin F. (CV-15) ...... 121 Liu J. (AR-11) ...... 40 Liu W. (EX-05) ...... 196 Li X. (AW-07) ...... 51 Lin G. (GS-04) ...... 256 Liu J. (BF-11) ...... 67 Liu W. (FQ-09) ...... 216 Li X. (AX-09) ...... 53 Lin H. (AT-14) ...... 45 Liu J. (BH-13) ...... 72 Liu W. (FR-04) ...... 217 Li X. (BF-13) ...... 67 Lin H. (EE-06) ...... 170 Liu J. (BV-01) ...... 85 Liu W. (GV-05) ...... 262 Li X. (BT-16) ...... 83 Lin H. (FR-15) ...... 219 Liu J. (BV-07) ...... 86 Liu W. (GV-10) ...... 262 Li X. (CT-17) ...... 116 Lin H. (FW-07) ...... 229 Liu J. (BV-09) ...... 86 Liu X. (AB-07) ...... 19 Li X. (DF-12) ...... 137 Lin H. (GG-04) ...... 245 Liu J. (CF-14) ...... 101 Liu X. (AC-06) ...... 21 Li X. (DF-15) ...... 137 Lin H.Q. (ED-08) ...... 168 Liu J. (CG-08) ...... 103 Liu X. (AP-03) ...... 35 Li X. (DR-13) ...... 149 Lin J. (BD-07) ...... 61 Liu J. (DG-10) ...... 139 Liu X. (AU-06) ...... 47 Li Y. (AS-16) ...... 43 Lin J. (CV-14) ...... 121 Liu J. (DV-04) ...... 156 Liu X. (AV-03) ...... 49 Li Y. (BC-10) ...... 59 Lin J. (EF-11) ...... 172 Liu J. (EB-01) ...... 163 Liu X. (BV-09) ...... 86 Li Y. (BQ-16) ...... 76 Lin J.G. (BD-07) ...... 61 Liu J. (EF-05) ...... 171 Liu X. (BV-12) ...... 87 Li Y. (BV-04) ...... 86 Lin J.G. (BP-06) ...... 73 Liu J. (EQ-02) ...... 180 Liu X. (CQ-01) ...... 109 Li Y. (CG-14) ...... 104 Lin J.G. (FS-08) ...... 220 Liu J. (EQ-05) ...... 181 Liu X. (CT-16) ...... 116 Li Y. (CR-12) ...... 112 Lin J.G. (HB-07) ...... 266 Liu J. (EV-14) ...... 193 Liu X. (DR-03) ...... 147 Li Y. (CX-01) ...... 123 Lin K. (DX-07) ...... 160 Liu J. (FD-11) ...... 204 Liu X. (DV-11) ...... 157 Li Y. (CX-10) ...... 124 Lin K. (EP-08) ...... 179 Liu J. (FF-11) ...... 208 Liu X. (EV-02) ...... 192 Li Y. (DH-07) ...... 141 Lin K. (EP-09) ...... 179 Liu J. (GS-03) ...... 256 Liu X. (EX-02) ...... 196 Li Y. (EV-13) ...... 193 Lin K. (EP-10) ...... 179 Liu J. (GV-06) ...... 262 Liu X. (EX-04) ...... 196 Li Y. (EW-13) ...... 195 Lin K.F. (EP-03) ...... 178 Liu J. (HG-01) ...... 276 Liu X. (FG-02) ...... 208 Li Y. (FA-01) ...... 197 Lin M. (AD-07) ...... 24 Liu K. (AD-05) ...... 23 Liu X. (FW-08) ...... 229 Li Y. (FS-10) ...... 220 Lin M. (DC-12) ...... 130 Liu K. (AF-01) ...... 27 Liu X. (GD-12) ...... 239 Li Y. (GR-14) ...... 255 Lin M. (EV-01) ...... 192 Liu K. (CR-05) ...... 111 Liu X. (GP-08) ...... 250 Li Y. (GS-02) ...... 256 Lin P. (FH-09) ...... 211 Liu K.C. (CS-09) ...... 114 Liu X. (GU-14) ...... 261 Li Y. (GT-13) ...... 259 Lin S. (BG-03) ...... 68 Liu K. (EP-14) ...... 180 Liu X. (GV-06) ...... 262 Li Y. (GV-05) ...... 262 Lin S. (ET-12) ...... 188 Liu K. (FP-11) ...... 214 Liu Y. (AV-09) ...... 49 Li Y. (GV-12) ...... 262 Lin T. (DH-14) ...... 142 Liu K. (GR-11) ...... 255 Liu Y. (BD-08) ...... 61 Li Y. (GV-13) ...... 262 Lin T. (EC-03) ...... 165 Liu K. (HE-06) ...... 272 Liu Y. (BV-04) ...... 86 Li Z. (GH-09) ...... 248 Lin T. (EP-10) ...... 179 Liu L. (BV-07) ...... 86 Liu Y. (BV-10) ...... 86 Li Z. (GV-04) ...... 261 Lin T. (GT-04) ...... 258 Liu L. (CD-11) ...... 96 Liu Y. (CX-10) ...... 124 Li Z. (HG-07) ...... 277 Lin W. (BB-04) ...... 55 Liu L. (CR-12) ...... 112 Liu Y. (EP-02) ...... 178 Li-jun N. (DS-08) ...... 150 Lin W. (EE-06) ...... 170 Liu L. (DT-09) ...... 152 Liu Y. (EV-03) ...... 192 Li-Xia W. (AR-01) ...... 39 Lin W. (FU-10) ...... 225 Liu L. (EV-02) ...... 192 Liu Y. (EV-07) ...... 193 Liang J. (FR-15) ...... 219 Lin Y. (DT-03) ...... 151 Liu L. (FA-01) ...... 197 Liu Y. (FB-10) ...... 200 Liang P. (DP-04) ...... 143 Lin Y. (DT-06) ...... 152 Liu L. (GF-13) ...... 244 Liu Y. (FP-07) ...... 213 Liang S. (GU-03) ...... 259 Lin Y.H. (GV-14) ...... 263 Liu L.Q. (BA-02) ...... 54 Liu Y. (FP-15) ...... 214 Liang S. (HB-09) ...... 266 Lin Z. (BQ-07) ...... 75 Liu L.Q. (GC-06) ...... 236 Liu Y. (FS-08) ...... 220 Liang W. (FR-11) ...... 218 Lin Z. (CD-12) ...... 96 Liu L.Y. (EX-07) ...... 197 Liu Y. (FT-14) ...... 223 Liang Y. (AS-01) ...... 41 Lin Z. (EW-13) ...... 195 Liu M. (AP-08) ...... 36 Liu Y. (FW-10) ...... 229 Liang Y. (BR-15) ...... 78 Linares Mardegan J. (ED-01) ...... 167 Liu M. (BR-04) ...... 77 Liu Y. (GT-03) ...... 258 Liang Y. (DX-13) ...... 161 Linderman K. (EQ-07) ...... 181 Liu M. (DT-09) ...... 152 Liu Y. (GV-03) ...... 261 Liao C. (EG-04) ...... 174 Linderman K. (FG-11) ...... 210 Liu M. (EQ-02) ...... 180 Liu Y. (GV-05) ...... 262 Liao C. (EG-14) ...... 175 Lindner J. (CU-07) ...... 118 Liu M. (ES-01) ...... 185 Liu Y. (GV-12) ...... 262 Liao K. (AS-15) ...... 43 Lindner J. (DG-01) ...... 138 Liu M. (ES-03) ...... 185 Liu Z. (EV-02) ...... 192 Liao K. (AW-01) ...... 50 Lindner P. (BF-06) ...... 66 Liu M. (GS-03) ...... 256 Liu Z.J. (CT-17) ...... 116 Liao K. (FP-02) ...... 213 Linwen J. (DR-11) ...... 148 Liu P. (AV-03) ...... 49 Livache T. (BH-02) ...... 70 Liao S. (EE-06) ...... 170 Liou S. (CH-06) ...... 105 Liu P. (BV-12) ...... 87 Livesey K. (BH-10) ...... 72 Liao Y. (AX-12) ...... 54 Liou S. (CH-10) ...... 105 Liu P. (CQ-01) ...... 109 Lo C.K. (BR-06) ...... 77 Liao Z. (GQ-11) ...... 253 Little C. (FH-11) ...... 212 Liu P. (DF-02) ...... 135 LoBue M. (AH-06) ...... 33 Liebing N. (DU-10) ...... 154 Litvinov D. (AS-01) ...... 41 Liu Q. (AU-06) ...... 47 LoBue M. (ER-15) ...... 184 Liebl M. (EW-12) ...... 195 Litvinov D. (DX-13) ...... 161 Liu Q. (BR-07) ...... 77 Locatelli A. (AU-14) ...... 48 Liedke M. (ET-03) ...... 187 Litvintsev I. (BW-05) ...... 87 Liu Q. (CT-16) ...... 116 Locatelli A. (DB-03) ...... 126 Liew Y. (BC-03) ...... 58 Liu C. (CR-07) ...... 112 Liu Q. (ES-12) ...... 186 Locatelli A. (FC-05) ...... 201 Lim C. (EW-06) ...... 195 Liu C. (CR-08) ...... 112 Liu Q. (GP-08) ...... 250 Locatelli N. (BG-04) ...... 68 312 PROGRAM PROGRAM 313

Locatelli N. (EH-09) ...... 177 Luning J. (FB-08) ...... 199 Maiden M.D. (GP-01) ...... 249 Manzin A. (GR-03) ...... 254 Locatelli N. (GP-05) ...... 249 Luo C. (CU-10) ...... 118 Mair L.O. (GR-13) ...... 255 Marangolo M. (CF-03) ...... 99 Lochner E. (EQ-08) ...... 181 Luo C. (ET-02) ...... 187 Majcher A.M. (ES-07) ...... 185 Maranville B. (FC-02) ...... 200 Lodewijk K. (GG-02) ...... 245 Luo G. (BP-06) ...... 73 Majetich S. (EE-07) ...... 170 March S.D. (GR-09) ...... 254 Lodya L.A. (CQ-10) ...... 110 Luo Q. (DT-08) ...... 152 Majetich S.A. (BS-15) ...... 81 Marcin J. (CG-01) ...... 101 Lofland S. (AF-10) ...... 29 Luo Y. (CD-12) ...... 96 Majetich S.A. (DE-06) ...... 134 Marcin J. (EF-04) ...... 171 Lofland S.E. (CE-04) ...... 98 Luo Y. (FG-01) ...... 208 Majetich S.A. (DR-05) ...... 148 Marcin J. (EF-14) ...... 173 Lomakin V. (AH-12) ...... 34 Lupo P. (BE-13) ...... 64 Majetich S.A. (HE-04) ...... 272 Marcondes T.L. (BU-13) ...... 85 Lomakin V. (BQ-03) ...... 75 Lupu N. (AR-07) ...... 40 Majumdar S. (DD-08) ...... 131 Mardegan J.R. (CQ-09) ...... 110 Lomakin V. (BT-06) ...... 82 Lupu N. (AR-15) ...... 41 Makarov A. (EH-04) ...... 176 Marie X. (HB-09) ...... 266 Lomakin V. (BX-11) ...... 89 Lupu N. (CF-06) ...... 100 Makarov D. (CE-06) ...... 98 Marín P. (FR-02) ...... 217 Lomakin V. (DB-04) ...... 126 Lupu N. (DG-04) ...... 138 Maki T. (FF-03) ...... 206 Marinescu M. (BV-01) ...... 85 Lomakin V. (EH-14) ...... 178 Lupu N. (EE-11) ...... 170 Makino A. (AR-02) ...... 39 Marinescu M. (DF-02) ...... 135 Longo E. (GS-08) ...... 256 Lussani F. (ED-01) ...... 167 Makino A. (BR-15) ...... 78 Marinescu M. (DG-10) ...... 139 Lookman T. (BE-02) ...... 62 Lüttich M. (EU-12) ...... 191 Makino A. (CG-05) ...... 102 Marinescu M. (EV-14) ...... 193 Lopes A.l. (FS-13) ...... 221 Lutz C.P. (FD-01) ...... 202 Makino A. (DG-04) ...... 138 Markandeyulu G. (CG-07) ...... 102 Lopez A. (AU-08) ...... 47 Lv H. (AS-09) ...... 42 Makinose Y. (DW-08) ...... 159 Markou A. (DX-01) ...... 160 López J.L. (FW-09) ...... 229 Lv Y. (DR-09) ...... 148 Malagò P. (AC-03) ...... 21 Markovich G. (DE-06) ...... 134 Lopez K. (DF-14) ...... 137 Lv Y. (EU-15) ...... 191 Malagò P. (BU-10) ...... 84 Marmion S. (EC-09) ...... 166 López Maldonado K.L. (GU-08) . . .260 Lv Y. (GQ-01) ...... 251 Malec C. (BB-08) ...... 56 Marques-Ferreira P. (DQ-13) ...... 146 Lopez-Barbera J.F. (CC-09) ...... 94 Lynch C.S. (GB-06) ...... 233 Malen J. (FE-08) ...... 205 Marrows C. (AB-01) ...... 18 Lopez-Barbera J.F. (FP-11) ...... 214 Lynn J.W. (AE-06) ...... 26 Malinowski G. (FB-08) ...... 199 Marrows C. (BC-06) ...... 58 Lopusnik R. (FT-06) ...... 222 Lynn K.G. (CG-10) ...... 103 Malinowski G. (GD-01) ...... 237 Marrows C. (DD-02) ...... 130 Lorenz V.O. (FA-03) ...... 198 Lyubutin I. (DW-07) ...... 159 Malkinski L.M. (AT-08) ...... 45 Marrows C.H. (AG-07) ...... 31 Losby J.E. (BG-12) ...... 69 Lyubutin I. (ER-11) ...... 184 Malléjac N. (HD-05) ...... 270 Marrows C.H. (CC-03) ...... 93 Lostun M. (CF-06) ...... 100 Mamica S. (BU-08) ...... 84 Marrows C.H. (DD-05) ...... 131 Lostun M. (EE-11) ...... 170 - M - Manabe A. (AV-12) ...... 50 Marrows C.H. (EB-06) ...... 164 Losuwan T. (GW-02) ...... 263 Manabe A. (FF-04) ...... 206 Marrows C.H. (ET-15) ...... 189 Lou G. (FP-04) ...... 213 Ma B.Y. (EX-07) ...... 197 Manabe A. (FF-05) ...... 207 Marrows C.H. (GH-03) ...... 247 Lou J. (FT-14) ...... 223 Ma L. (GQ-03) ...... 252 Manabe A. (FF-07) ...... 207 Marsten E.R. (GQ-04) ...... 252 Lou Y. (BR-04) ...... 77 Ma M. (CV-09) ...... 120 Manabe A. (FF-12) ...... 208 Marti X. (EB-01) ...... 163 Loughran T.J. (EH-10) ...... 177 Ma Q. (AP-06) ...... 35 Manchanda P. (AF-05) ...... 28 Martin S.Y. (BG-10) ...... 69 Loureiro L.T. (GG-11) ...... 246 Ma Q. (CA-03) ...... 90 Manchanda P. (CH-06) ...... 105 Martincic E. (HG-03) ...... 276 Loving M. (AG-07) ...... 31 Ma Q. (CD-01) ...... 95 Manchanda P. (DS-07) ...... 150 Martinez E. (GC-10) ...... 236 Loving M. (ET-15) ...... 189 Ma Q. (GU-02) ...... 259 Manchanda P. (FV-12) ...... 228 Martinez J. (AB-05) ...... 19 Löwe K. (DF-07) ...... 136 Ma S. (CW-09) ...... 122 Manchon A. (BB-01) ...... 55 Martins S.A. (BH-08) ...... 71 Lu B. (CS-10) ...... 114 Ma S. (DR-13) ...... 149 Manchon A. (DH-06) ...... 140 Martirosyan K. (BH-11) ...... 72 Lu C. (AS-05) ...... 42 Ma S. (DX-09) ...... 161 Manchon A. (DP-12) ...... 144 Marty A. (AU-10) ...... 47 Lu C. (AS-13) ...... 43 Ma S. (EF-09) ...... 172 Manchon A. (FA-04) ...... 198 Marty A. (AW-05) ...... 51 Lu C. (AW-10) ...... 51 Ma S. (EW-05) ...... 194 Mancoff F.B. (BA-01) ...... 54 Marty A. (BB-07) ...... 56 Lu C. (DS-09) ...... 150 Ma Y. (AV-10) ...... 49 Mandal P. (DD-12) ...... 132 Marty A. (BP-14) ...... 74 Lu F. (EV-13) ...... 193 Ma Y. (BV-09) ...... 86 Mandru A. (GE-01) ...... 240 Marty A. (BU-09) ...... 84 Lu H. (FX-08) ...... 231 Ma Y. (GV-06) ...... 262 Manfrinetti P. (DQ-02) ...... 145 Marty A. (BU-15) ...... 85 Lu H. (GU-05) ...... 260 Maccariello D. (HC-01) ...... 267 Mangin S. (DB-04) ...... 126 Maruyama S. (AE-11) ...... 27 Lu J. (EG-13) ...... 175 Maccariello D. (HC-11) ...... 269 Mangin S. (DP-15) ...... 144 Maruyama S. (AF-10) ...... 29 Lu J. (FS-15) ...... 221 MacDonald A.H. (DH-08) ...... 141 Mangin S. (GD-01) ...... 237 Maruyama S. (CE-04) ...... 98 Lu L. (CU-13) ...... 119 Macedo Garitezi T. (CS-03) ...... 113 Manh D. (DW-02) ...... 158 Marysko M. (AQ-03) ...... 37 Lu M. (GR-08) ...... 254 Macedo Garitezi T. (CS-04) ...... 113 Manipatruni S. (CD-08) ...... 96 Marysko M. (DE-10) ...... 134 Lu P. (FE-07) ...... 205 Machado F.A. (EX-03) ...... 196 Manipatruni S. (CP-14) ...... 108 Masaaki F. (BR-13) ...... 78 Lu Q. (BV-10) ...... 86 Machida K. (FP-04) ...... 213 Manipatruni S. (GT-09) ...... 258 Masamune K. (AW-11) ...... 51 Lu Q. (GV-03) ...... 261 Machida T. (GC-11) ...... 237 Mankey G. (AG-13) ...... 32 Masashi S. (BP-04) ...... 73 Lu Q. (GV-05) ...... 262 Macià F. (CB-12) ...... 92 Mankey G. (FV-11) ...... 227 Mascaró P. (CW-04) ...... 122 Lu Q. (GV-12) ...... 262 Maciakowski P. (AW-15) ...... 52 Mankey G.J. (ED-09) ...... 168 Mason S.J. (DP-16) ...... 144 Lu Y. (AT-11) ...... 45 Madami M. (AC-02) ...... 20 Mann A. (EU-12) ...... 191 Masubuchi S. (GC-11) ...... 237 Lu Y. (AT-12) ...... 45 Madami M. (AC-05) ...... 21 Manna K. (DD-07) ...... 131 Mata-Chávez R.I. (BG-14) ...... 70 Lu Y. (CQ-04) ...... 109 Madami M. (AH-02) ...... 33 Manna K. (HH-09) ...... 279 Matarranz R. (BR-09) ...... 78 Lu Y. (DP-11) ...... 144 Madami M. (BU-08) ...... 84 Manna S.K. (GG-01) ...... 244 Matarranz R. (FR-08) ...... 218 Lu Y. (FS-14) ...... 221 Madami M. (CF-03) ...... 99 Mansanares A.M. (FQ-01) ...... 215 Mathias S. (EU-08) ...... 190 Lu Y. (HB-09) ...... 266 Maehara H. (BS-09) ...... 80 Mansell R. (CC-01) ...... 93 Mathias S. (FB-05) ...... 199 Lubarda M. (DB-04) ...... 126 Maehara H. (BS-10) ...... 80 Mansell R. (CC-02) ...... 93 Matias V. (GS-02) ...... 256 Lubarda M. (EH-14) ...... 178 Maehara H. (FU-14) ...... 225 Mansell R. (CC-10) ...... 94 Matko I. (CG-01) ...... 101 Lucas M. (FV-02) ...... 226 Maehara H. (HA-05) ...... 265 Mansell R. (ET-10) ...... 188 Matsuda Y. (GU-09) ...... 260 Lucis M. (GF-10) ...... 244 Maeno Y. (CS-01) ...... 113 Mantovan R. (AG-12) ...... 32 Matsugami K. (FC-06) ...... 201 Lucis M.J. (DF-03) ...... 135 Magni A. (CG-15) ...... 104 Mantovan R. (BS-16) ...... 81 Matsui T. (DT-07) ...... 152 Ludwig F. (BH-03) ...... 71 Magnus F. (AF-07) ...... 28 Mantovan R. (FS-09) ...... 220 Matsuki H. (CR-10) ...... 112 Luhrs N. (FG-13) ...... 210 Magrez A. (DS-01) ...... 149 Mantovan R. (FU-10) ...... 225 Matsuki H. (CR-11) ...... 112 Luhrs N. (HD-03) ...... 270 Mahendru D. (CC-10) ...... 94 Mantovan R. (HC-06) ...... 268 Matsukura F. (DC-09) ...... 129 Lukashev P.V. (EB-11) ...... 164 Maheshwar S. (GV-07) ...... 262 Manzin A. (AS-04) ...... 42 Matsukura F. (DC-10) ...... 129 Lukaszew R.A. (EE-09) ...... 170 Mahmoudi H. (EH-04) ...... 176 Manzin A. (BX-03) ...... 89 Matsukura F. (DH-09) ...... 141 Lukes I. (DE-10) ...... 134 Mai T T.T. (EW-03) ...... 194 Manzin A. (DX-06) ...... 160 Matsumoto M. (DU-14) ...... 155 Lumsden M. (HH-01) ...... 278 Maicas M. (GD-12) ...... 239 Manzin A. (EA-01) ...... 161 Matsumoto R. (AC-01) ...... 20 Lund S. (DE-03) ...... 133 Maiden M. (DA-02) ...... 124 Manzin A. (FU-05) ...... 224 Matsumoto R. (CB-01) ...... 91 314 PROGRAM PROGRAM 315

Matsumoto R. (CB-11) ...... 92 McVitie S. (BC-06) ...... 58 Miao B. (EC-10) ...... 166 Miyake T. (BF-02) ...... 65 Matsumoto R. (CP-01) ...... 106 McVitie S. (CC-03) ...... 93 Miao X. (EF-07) ...... 172 Miyamoto N. (AV-12) ...... 50 Matsumoto R. (EH-13) ...... 178 McVitie S. (DB-11) ...... 127 Mibu K. (ET-08) ...... 188 Miyamoto N. (FF-05) ...... 207 Matsumoto R. (FU-14) ...... 225 McVitie S. (FC-13) ...... 202 Mibu K. (FP-07) ...... 213 Miyamoto Y. (DU-04) ...... 154 Matsumoto R. (HA-05) ...... 265 Md Din M. (CF-10) ...... 100 Michaela K. (CC-06) ...... 93 Miyamoto Y. (FU-06) ...... 224 Matsuo T. (BQ-02) ...... 75 Md Din M. (DD-13) ...... 132 Michalik J.M. (BB-12) ...... 57 Miyao M. (BP-12) ...... 74 Matsuo T. (GG-05) ...... 245 Md Din M. (EF-02) ...... 171 Michel J. (BU-15) ...... 85 Miyashita E. (DU-04) ...... 154 Matsushita N. (DW-08) ...... 159 Md Din M.F. (CQ-13) ...... 110 Michels A. (BF-06) ...... 66 Miyashita E. (FU-06) ...... 224 Matsushita N. (HD-12) ...... 271 Md Din M.F. (GQ-03) ...... 252 Midya A. (DD-12) ...... 132 Miyashita Y. (EW-08) ...... 195 Matsuyama K. (BU-03) ...... 83 Méasson M. (AE-09) ...... 26 Mifune T. (GG-05) ...... 245 Miyata K. (BQ-02) ...... 75 Matsuyama K. (CT-20) ...... 117 Meckenstock R. (DG-01) ...... 138 Mihajlovic´ M.D. (BX-02) ...... 88 Miyawaki T. (CF-09) ...... 100 Matsuyama K. (FP-03) ...... 213 Mefford T.O. (HE-05) ...... 272 Mikuszeit N. (BU-15) ...... 85 Miyawaki T. (FX-01) ...... 230 Matsuyama K. (FU-02) ...... 224 Mehedi A. (FV-07) ...... 227 Milanovic N. (FR-03) ...... 217 Miyazaki T. (AP-06) ...... 35 Matsuyama T. (BP-07) ...... 73 Mehta A. (DF-14) ...... 137 Miles J.J. (BX-02) ...... 88 Miyazaki T. (AV-05) ...... 49 Mattana R. (DC-11) ...... 129 Mehta V. (EA-02) ...... 162 Miller C. (HC-02) ...... 267 Miyazaki T. (BA-05) ...... 55 Mattana R. (HC-10) ...... 269 Mehta V.V. (BE-01) ...... 62 Miller C.W. (AD-09) ...... 24 Miyazaki T. (CA-03) ...... 90 Matthew J. (HC-12) ...... 269 Mehta V.V. (BE-12) ...... 64 Miller C.W. (EF-13) ...... 173 Miyazaki T. (CD-01) ...... 95 Matthew J.A. (BE-11) ...... 64 Mehta V.V. (HF-11) ...... 275 Miller G.J. (ED-05) ...... 168 Miyazaki T. (CU-06) ...... 118 Matutes Aquino J. (BV-03) ...... 86 Meier G. (AC-12) ...... 22 Miller J.A. (BB-10) ...... 56 Miyazaki T. (EU-04) ...... 190 Matutes Aquino J.A. (BQ-10) ...... 76 Meier G. (BG-11) ...... 69 Miltat J. (BG-14) ...... 70 Miyazaki T. (GB-13) ...... 234 Matutes Aquino J.A. (FQ-02) ...... 215 Meier G. (BP-07) ...... 73 Miltat J. (DB-07) ...... 126 Miyazaki T. (GU-02) ...... 259 Matutes Aquino J.A. (GU-08) . . . . .260 Meier G. (DB-02) ...... 125 Miltat J. (HE-07) ...... 273 Miyazaki T. (HD-01) ...... 270 Mawass M. (CF-09) ...... 100 Meier G. (GE-05) ...... 240 Min B. (AB-03) ...... 18 Mizuguchi M. (AG-04) ...... 30 Mawass M. (CT-15) ...... 116 Meinert M. (FX-05) ...... 230 Min B. (AU-05) ...... 46 Mizuguchi M. (CQ-05) ...... 109 Mawass M. (DB-13) ...... 127 Meisel M.W. (FD-08) ...... 203 Min B. (BP-08) ...... 73 Mizuguchi M. (CU-11) ...... 118 Mawass M.A. (BG-02) ...... 68 Melamed C.L. (ES-08) ...... 186 Min B. (CP-15) ...... 108 Mizukami S. (AP-06) ...... 35 May S. (BD-06) ...... 61 Melamed C.L. (ES-09) ...... 186 Min B. (DB-06) ...... 126 Mizukami S. (CA-03) ...... 90 May S. (DQ-12) ...... 146 Melander E. (GE-06) ...... 241 Min B. (FU-09) ...... 225 Mizukami S. (CD-01) ...... 95 Mayergoyz I. (BT-10) ...... 82 Melikhov Y. (BQ-09) ...... 76 Min B. (FU-15) ...... 226 Mizukami S. (CU-06) ...... 118 Mayergoyz I.D. (DP-09) ...... 143 Melikyan A. (GP-10) ...... 250 Min B. (FU-16) ...... 226 Mizukami S. (CU-11) ...... 118 Mayergoyz I.D. (EG-08) ...... 174 Melkebeek J.A. (CR-13) ...... 112 Min B.I. (FS-12) ...... 221 Mizukami S. (EU-04) ...... 190 Mayergoyz I.D. (EG-09) ...... 174 Melkov G.A. (AC-08) ...... 21 Min J. (EW-06) ...... 195 Mizukami S. (FB-11) ...... 200 Mayergoyz I.D. (GD-03) ...... 238 Melkov G.A. (HE-08) ...... 273 Miranda R. (HC-01) ...... 267 Mizukami S. (GB-13) ...... 234 Maynicke E. (GC-12) ...... 237 Mellnik A. (FA-01) ...... 197 Miranda R. (HC-11) ...... 269 Mizukami S. (GU-02) ...... 259 Mazaleyrat F. (AD-01) ...... 23 Melnikova S.V. (FR-12) ...... 218 Miron I. (DU-06) ...... 154 Mizukawa Y. (EE-10) ...... 170 Mazaleyrat F. (AH-06) ...... 33 Men H. (CG-13) ...... 103 Miron I.M. (AU-08) ...... 47 Mizunuma K. (BS-02) ...... 79 Mazaleyrat F. (ER-15) ...... 184 Menarini M. (BT-06) ...... 82 Miron M. (DB-05) ...... 126 Mizunuma K. (DC-09) ...... 129 Mazalski P. (ET-03) ...... 187 Menarini M. (BX-11) ...... 89 Mishra A. (DU-15) ...... 155 Mizuochi N. (CP-01) ...... 106 Maziewski A. (ET-03) ...... 187 Mendez H. (FT-09) ...... 222 Mishra R.K. (DF-06) ...... 136 Mizuochi N. (GB-02) ...... 233 McAtee S. (GR-09) ...... 254 Mendonca T.M. (FS-13) ...... 221 Mishra S. (BE-08) ...... 63 Mizushima K. (FT-01) ...... 221 McAvoy P. (BT-10) ...... 82 Menéndez E. (CC-09) ...... 94 Mishra S. (BV-08) ...... 86 Mizushima K. (FT-02) ...... 222 McCallum R.W. (GF-02) ...... 242 Meng F. (DR-09) ...... 148 Mishra S.R. (CW-10) ...... 122 Mo Z. (EF-11) ...... 172 McCallum R.W. (GF-03) ...... 242 Meng F. (FG-03) ...... 209 Mistrik J. (AT-07) ...... 45 Mochizuki A. (CD-05) ...... 95 McCallum W.R. (HD-11) ...... 271 Meng F. (FP-14) ...... 214 Mitani S. (AB-09) ...... 19 Mogilianski D. (FX-09) ...... 231 McCloy J. (EP-14) ...... 180 Meng F. (HG-05) ...... 277 Mitani S. (AG-03) ...... 30 Mohammadi J.B. (BF-03) ...... 65 McCloy J.S. (CW-02) ...... 121 Meng S. (FV-03) ...... 226 Mitani S. (AG-11) ...... 32 Mohanty J. (BG-02) ...... 68 McComb D. (GC-02) ...... 235 Meng Y. (FV-04) ...... 227 Mitani S. (CP-06) ...... 107 Mohapatra N. (HH-07) ...... 279 McCord J. (ET-03) ...... 187 Meng Z. (AU-02) ...... 46 Mitani S. (DC-05) ...... 128 Mohebbi M. (CR-16) ...... 113 McDonald I. (DV-14) ...... 157 Mentes T. (AU-14) ...... 48 Mitani S. (DH-10) ...... 141 Mohebbi M. (CX-07) ...... 123 McFadzean S. (AD-11) ...... 24 Mentes T.O. (DB-03) ...... 126 Mitani S. (GT-06) ...... 258 Mohebbi M. (CX-08) ...... 123 McGrouther D. (BC-06) ...... 58 Mentes T.O. (FC-05) ...... 201 Mitchell J. (HH-04) ...... 278 Mohebbi M. (GB-09) ...... 234 McGrouther D. (CC-03) ...... 93 Merazzo K.J. (GE-03) ...... 240 Mitra C. (HH-10) ...... 279 Mohseni M. (CB-07) ...... 92 McGrouther D. (DB-11) ...... 127 Mercer J.I. (GW-03) ...... 263 Mitrossilis D. (EW-14) ...... 196 Mohseni M. (EH-05) ...... 176 McGrouther D. (FC-13) ...... 202 Mertins H. (ED-02) ...... 167 Mitsumata C. (AV-12) ...... 50 Mohseni S. (CB-05) ...... 91 McHenry M. (BR-10) ...... 78 Mesa Una J. (GD-12) ...... 239 Mitsumata C. (BX-05) ...... 89 Mohseni S. (EH-02) ...... 176 McHenry M. (GD-12) ...... 239 Messerschmidt M. (FB-04) ...... 199 Mitsumata C. (DU-14) ...... 155 Mohseni S.M. (CP-02) ...... 106 McHenry M.E. (CG-03) ...... 102 Metaxas P. (DB-09) ...... 127 Miura K. (AC-09) ...... 22 Mohseni S.M. (DA-01) ...... 124 McHenry M.E. (CG-04) ...... 102 Metaxas P. (ET-04) ...... 187 Miura S. (BS-02) ...... 79 Mohseni S.M. (HC-02) ...... 267 McHenry M.E. (ER-14) ...... 184 Metaxas P. (FU-14) ...... 225 Miura S. (CD-05) ...... 95 Moisan N. (FB-08) ...... 199 McIntyre G.J. (AD-12) ...... 24 Metaxas P. (GP-04) ...... 249 Miura S. (CD-06) ...... 96 Molenkamp L. (EH-02) ...... 176 Mckinnon T. (AG-08) ...... 31 Metaxas P.J. (AU-13) ...... 48 Miura S. (DC-01) ...... 128 Mompean F. (GS-12) ...... 257 McKinnon T. (AP-04) ...... 35 Mewes C. (BF-03) ...... 65 Miura S. (GT-01) ...... 257 Moneck M. (CG-04) ...... 102 McKinnon T. (CC-08) ...... 94 Mewes C. (FV-11) ...... 227 Miwa S. (CP-01) ...... 106 Moneck M.T. (BS-03) ...... 79 Mckinnon T. (HF-12) ...... 275 Mewes T. (AG-13) ...... 32 Miwa S. (CP-05) ...... 107 Moneck M.T. (FU-12) ...... 225 McLaren M. (AG-07) ...... 31 Mewes T. (BF-03) ...... 65 Miwa S. (GB-02) ...... 233 Montazeri M. (EB-02) ...... 163 McLaren M. (EC-09) ...... 166 Mewes T. (CT-10) ...... 116 Miwa S. (GU-04) ...... 259 Monteblanco E. (EH-15) ...... 178 McLaughlin G. (FW-11) ...... 229 Meyer A. (DE-07) ...... 134 Miwa S. (HA-05) ...... 265 Monteiro G. (BH-08) ...... 71 McMichael R. (CU-14) ...... 119 Meyer M.S. (GF-10) ...... 244 Miwa Y. (AS-07) ...... 42 Monteiro P.M. (BD-05) ...... 60 McMichael R.D. (DU-08) ...... 154 Meyer T.L. (BC-13) ...... 59 Mix C. (CF-09) ...... 100 Montero - Muñoz M. (AQ-06) ...... 38 McMichael R.D. (GR-13) ...... 255 Miao B. (AH-10) ...... 34 Mix C. (FS-01) ...... 219 Montfrooij W. (BD-02) ...... 60 McMorrow D. (HH-01) ...... 278 Miao B. (DP-11) ...... 144 Mixon G. (BQ-06) ...... 75 Monti M. (FC-12) ...... 202 McVitie S. (AD-11) ...... 24 Miao B. (EC-07) ...... 166 Miyahara Y. (FC-09) ...... 201 Montoncello F. (AC-05) ...... 21 316 PROGRAM PROGRAM 317

Montoncello F. (EU-03) ...... 190 Mu C. (CT-16) ...... 116 Naganuma H. (GB-13) ...... 234 Nara T. (GR-10) ...... 255 Montoya E. (AP-04) ...... 35 Mu C. (GP-08) ...... 250 Naganuma H. (GB-14) ...... 235 Narayana C. (HH-09) ...... 279 Montoya E. (BC-02) ...... 58 Mu S. (CE-07) ...... 98 Nagasako M. (BS-13) ...... 80 Narayanan H. (AQ-07) ...... 38 Montoya E. (CC-08) ...... 94 Mubarok A. (DF-01) ...... 135 Nagasawa T. (FT-01) ...... 221 Narayanapillai K. (DH-11) ...... 141 Montoya E. (GC-03) ...... 235 Mubarok A. (DF-06) ...... 136 Nagasawa T. (FT-02) ...... 222 Narayanapillai K. (FU-04) ...... 224 Montoya E. (HF-12) ...... 275 Mubarok A. (DV-04) ...... 156 Nagase T. (CP-05) ...... 107 Narayanapillai K. (GB-11) ...... 234 Moodera J. (CA-01) ...... 90 Mudryk Y. (AP-12) ...... 36 Nagata M. (CB-13) ...... 92 Naseem S. (FV-08) ...... 227 Moodera J.S. (AB-02) ...... 18 Mudryk Y. (DQ-09) ...... 146 Nagel K. (BA-01) ...... 54 Nasi L. (BE-13) ...... 64 Moon C. (BP-08) ...... 73 Mudryk Y. (EF-10) ...... 172 Nahas J.J. (FP-06) ...... 213 Nasi L. (BS-16) ...... 81 Moon E. (BD-06) ...... 61 Muduli P.K. (DA-01) ...... 124 Naik A. (FH-04) ...... 211 Nasi L. (CF-08) ...... 100 Moon E. (DQ-12) ...... 146 Muduli P.K. (EU-09) ...... 190 Nair V.G. (CS-11) ...... 114 Nasirpouri F. (BW-05) ...... 87 Moon J. (CP-13) ...... 108 Mukhanov O. (DP-03) ...... 143 Naito A. (CS-02) ...... 113 Natarajarathinam A. (FT-05) ...... 222 Moon J. (EU-01) ...... 189 Mukherjee D. (BE-09) ...... 64 Naito T. (EQ-13) ...... 182 Natsui M. (CD-05) ...... 95 Moon J. (GP-02) ...... 249 Mukherjee D. (DS-14) ...... 151 Nakabayashi M. (AS-10) ...... 43 Natsui M. (CD-09) ...... 96 Moon K. (AU-01) ...... 46 Mukherjee P. (AQ-09) ...... 38 Nakagawa H. (AW-11) ...... 51 Natsumeda M. (FF-03) ...... 206 Moon K. (FU-15) ...... 226 Mukherjee P. (BE-09) ...... 64 Nakagawa K. (CT-02) ...... 115 Navau C. (FP-11) ...... 214 Moon K. (FU-16) ...... 226 Mukherjee P. (DS-14) ...... 151 Nakagawa N. (DG-05) ...... 138 Nayak A.K. (AB-11) ...... 20 Moore T.A. (CC-03) ...... 93 Mukherjee P. (EP-04) ...... 179 Nakagawa S. (BS-01) ...... 79 Ndiaye P.B. (BB-01) ...... 55 Moorsom T. (CP-08) ...... 107 Mukherjee P. (EW-03) ...... 194 Nakagawa S. (BS-08) ...... 80 Nebashi R. (CD-06) ...... 96 Morais P.C. (EW-09) ...... 195 Mukherjee P. (HE-09) ...... 273 Nakagawa S. (BT-17) ...... 83 Nebashi R. (CD-09) ...... 96 Morales M. (DR-02) ...... 147 Mukherjee S. (DC-02) ...... 128 Nakagawa S. (DW-08) ...... 159 Neelam R. (DF-05) ...... 136 Morales M.P. (DE-01) ...... 133 Mukhin A. (AE-10) ...... 26 Nakagawa S. (HD-07) ...... 271 Neelam R.V. (FR-04) ...... 217 Morán O. (GS-15) ...... 257 Mukhopadhyay P.K. (FR-01) ...... 217 Nakagawa S. (HF-08) ...... 275 Neelam V. (GV-02) ...... 261 Morcrette M. (BH-02) ...... 70 Mukovskiy Y.M. (FS-11) ...... 221 Nakai T. (AR-06) ...... 40 Negoita M. (BB-10) ...... 56 Morcrette M. (FH-10) ...... 212 Müller L. (EA-05) ...... 162 Nakajima M. (HD-01) ...... 270 Neige J. (HD-05) ...... 270 Morel R. (AW-05) ...... 51 Müller M. (GH-01) ...... 246 Nakamura K. (FC-06) ...... 201 Nelayah J. (AF-11) ...... 29 Moreland J. (CH-10) ...... 105 Mundle R.M. (DS-10) ...... 150 Nakamura K. (GG-06) ...... 245 Nelson A.D. (AT-13) ...... 45 Moreland J. (DU-16) ...... 155 Munira K. (CD-10) ...... 96 Nakamura S. (DX-02) ...... 160 Nelson C. (EB-01) ...... 163 Moreland J. (GR-12) ...... 255 Muñoz A. (FD-11) ...... 204 Nakamura T. (FF-02) ...... 206 Nembach H. (FB-05) ...... 199 Moreno L.M. (CG-12) ...... 103 Muñoz M. (BC-09) ...... 59 Nakamura Y. (GW-06) ...... 263 Nembach H.T. (BC-05) ...... 58 Morettini V. (EG-12) ...... 175 Muñoz M. (GP-05) ...... 249 Nakane R. (GT-06) ...... 258 Nembach H.T. (BC-07) ...... 59 Morgan J. (FU-10) ...... 225 Muñoz M. (HC-11) ...... 269 Nakano M. (BR-12) ...... 78 Nembach H.T. (CC-07) ...... 94 Mori T. (BD-03) ...... 60 Münzenberg M. (EB-04) ...... 163 Nakano M. (BV-13) ...... 87 Nembach H.T. (EU-08) ...... 190 Morikawa S. (GC-11) ...... 237 Münzenberg M. (EH-07) ...... 177 Nakano M. (DG-06) ...... 138 Nembach H.T. (EW-15) ...... 196 Morimoto Y. (AV-02) ...... 48 Münzenberg M. (EU-12) ...... 191 Nakano M. (DV-07) ...... 157 Nemsak S. (FC-02) ...... 200 Morimura T. (DV-07) ...... 157 Murahata M. (BS-02) ...... 79 Nakano M. (EV-08) ...... 193 Nespolo M. (DQ-13) ...... 146 Morisako A. (DV-11) ...... 157 Murahata M. (CD-06) ...... 96 Nakano M. (EV-09) ...... 193 Nestor H. (GS-02) ...... 256 Morisako A. (EX-02) ...... 196 Murakami M. (CE-04) ...... 98 Nakano Y. (EP-15) ...... 180 Neu V. (HF-05) ...... 274 Morisako A. (EX-04) ...... 196 Murakami S. (AC-01) ...... 20 Nakao H. (AF-13) ...... 29 Neudert A. (BG-01) ...... 67 Morishita J. (FP-07) ...... 213 Murakami T. (EC-06) ...... 166 Nakashima Y. (DU-16) ...... 155 Neumann A. (DE-07) ...... 134 Morita A. (GT-01) ...... 257 Muraoka H. (BT-03) ...... 81 Nakashima Y. (GR-12) ...... 255 Nevirkovets I.P. (CB-08) ...... 92 Moritz J. (AD-08) ...... 24 Muraoka H. (GW-04) ...... 263 Nakata H. (BT-05) ...... 81 Ney A. (AA-03) ...... 17 Moriya R. (GC-11) ...... 237 Muraoka H. (GW-06) ...... 263 Nakatani R. (EP-15) ...... 180 Ney V. (AA-03) ...... 17 Moriya T. (BT-05) ...... 81 Muraoka H. (GW-07) ...... 264 Nakatani R. (GT-01) ...... 257 Ng S. (EE-08) ...... 170 Moriya T. (FE-06) ...... 205 Murgulescu I. (CF-06) ...... 100 Nakatani Y. (AU-11) ...... 47 Ng V. (GE-13) ...... 242 Moriyama T. (CB-13) ...... 92 Murnane M.M. (EU-08) ...... 190 Nakatani Y. (BA-05) ...... 55 Ng V. (GR-05) ...... 254 Moriyama T. (EU-01) ...... 189 Murnane M.M. (FB-05) ...... 199 Nakatani Y. (DP-10) ...... 144 Ngatu G. (FW-02) ...... 228 Moriyoshi C. (AX-11) ...... 53 Murthy S. (BA-02) ...... 54 Nakatani Y. (DX-02) ...... 160 Ngo D. (AU-02) ...... 46 Morley S.A. (DD-05) ...... 131 Murthy S. (GC-06) ...... 236 Nakatani Y. (FU-07) ...... 224 Nguyen A. (DU-08) ...... 154 Morosawa Y. (CS-02) ...... 113 Murzina T.V. (EE-09) ...... 170 Nakayama T. (AD-13) ...... 25 Nguyen C. (BB-07) ...... 56 Moroz E. (BQ-11) ...... 76 Mutta V. (GH-10) ...... 248 Nakotte H. (FD-07) ...... 203 Nguyen H. (CF-12) ...... 101 Moroz Y. (BQ-11) ...... 76 Myers J. (HD-12) ...... 271 Naletov V. (EH-08) ...... 177 Nguyen H.T. (CU-04) ...... 117 Mosendz O. (BT-07) ...... 82 Myrasov O. (ED-09) ...... 168 Naletov V. (EH-09) ...... 177 Nguyen M. (DF-12) ...... 137 Mosendz O. (HF-05) ...... 274 Naletov V. (GP-05) ...... 249 Nguyen M. (DH-04) ...... 140 Mosivand S. (AH-09) ...... 34 - N - Naletov V.V. (BC-09) ...... 59 Nguyen M. (FA-01) ...... 197 Mostovoy M. (AE-07) ...... 26 Nam J. (AW-04) ...... 51 Nguyen P. (DF-04) ...... 136 Moubah R. (AF-07) ...... 28 N’Diaye A.T. (FC-12) ...... 202 Nam Y. (GE-02) ...... 240 Nguyen T. (HC-02) ...... 267 Mougin A. (AU-13) ...... 48 Na S. (CF-07) ...... 100 Namai A. (HD-01) ...... 270 Nguyen T.V. (AQ-16) ...... 39 Mougin A. (DP-10) ...... 144 Nabaei V. (AS-04) ...... 42 Namavar F. (EP-14) ...... 180 Nguyen T.V. (FD-09) ...... 203 Moulin J. (HG-03) ...... 276 Nabaei V. (DX-06) ...... 160 Namizaki Y. (DR-12) ...... 148 Nguyen V. (AU-10) ...... 47 Moutafis C. (BG-02) ...... 68 Nabaei V. (FU-05) ...... 224 Nan T. (BR-08) ...... 78 Nguyen V. (AU-14) ...... 48 Mouton L. (AD-01) ...... 23 Nadi M. (BW-05) ...... 87 Nan T. (CH-05)* ...... 105 Nguyen V. (BB-07) ...... 56 Moya C. (DE-01) ...... 133 Nagahama T. (GU-09) ...... 260 Nan T. (CR-01) ...... 111 Nguyen V. (BU-09) ...... 84 Moyerman S. (FC-04) ...... 201 Nagamine L.C. (DW-05) ...... 158 Nan T. (DS-11) ...... 150 Nguyen V. (BV-09) ...... 86 Mruczkiewicz . (BU-08) ...... 84 Nagamine M. (CP-05) ...... 107 Nan T. (DS-13) ...... 151 Nguyen V. (DF-02) ...... 135 Mryasov O. (AG-08) ...... 31 Nagamine Y. (BS-10) ...... 80 Nan T. (DS-15) ...... 151 Nguyen V. (GE-12) ...... 242 Mryasov O. (HF-12) ...... 275 Nagamine Y. (FU-14) ...... 225 Nan T. (EG-02) ...... 173 Nguyen V. (GV-06) ...... 262 Mryasov O.N. (AG-15) ...... 32 Naganuma H. (AC-11) ...... 22 Nan T. (ES-01) ...... 185 Nguyen X.P. (EW-03) ...... 194 Mryasov O.N. (AH-12) ...... 34 Naganuma H. (CU-06) ...... 118 Nan T. (GG-04) ...... 245 Nicholson D. (DG-13) ...... 139 Mryasov O.N. (CD-13) ...... 97 Naganuma H. (EU-13) ...... 191 Naoko M. (FF-01) ...... 206 Nicholson D.M. (ED-07) ...... 168 Mryasov O.N. (GT-08) ...... 258 Naganuma H. (FB-11) ...... 200 Nara T. (CH-01) ...... 104 Nicholson D.M. (EU-05) ...... 190 Mu C. (AU-06) ...... 47 Naganuma H. (FX-09) ...... 231 Nara T. (CH-07) ...... 105 Nickel F. (FC-12) ...... 202 318 PROGRAM PROGRAM 319

Nicklas M. (AB-11) ...... 20 Novosad V. (DU-12) ...... 155 Ohkubo T. (FF-02) ...... 206 Omari K.A. (FU-01) ...... 224 Nie Y. (EQ-07) ...... 181 Novosad V. (DU-13) ...... 155 Ohkubo T. (FF-11) ...... 208 Onabajo M. (CR-01) ...... 111 Nie Y. (EX-05) ...... 196 Novosad V. (FP-13) ...... 214 Ohkubo T. (GF-01) ...... 242 Onabajo M. (EG-02) ...... 173 Nie Y. (FG-04) ...... 209 Novosad V. (GP-06) ...... 249 Ohkubo T. (GF-13) ...... 244 Onbasli M.C. (EB-02) ...... 163 Nielsch K. (BW-08) ...... 88 Nowak J. (BA-02) ...... 54 Ohldag H. (DU-01) ...... 153 Onbasli M.C. (EC-02) ...... 165 Nielsch K. (DX-04) ...... 160 Nowak J.J. (GC-06) ...... 236 Ohldag H. (HH-04) ...... 278 Oner Y.-. (DQ-04) ...... 145 Nielsch K. (ES-14) ...... 186 Nowak S. (AD-01) ...... 23 Ohldag H. (HH-05) ...... 279 Ong B. (DW-03) ...... 158 Nielsch K. (GP-14) ...... 250 Nowak S. (ED-11) ...... 168 Ohno H. (BA-04) ...... 55 Ong K.P. (AF-12) ...... 29 Nielsen J. (AW-03) ...... 50 Nowak U. (BW-09) ...... 88 Ohno H. (BB-11) ...... 57 Ong P. (ES-06) ...... 185 Nielsen P.F. (BS-14) ...... 81 Nowak U. (EC-02) ...... 165 Ohno H. (BS-02) ...... 79 Ong W. (FE-08) ...... 205 Niemier M.T. (FP-06) ...... 213 Nowak U. (FB-06) ...... 199 Ohno H. (CD-05) ...... 95 Oniku O.D. (GF-11) ...... 244 Niimi Y. (CP-06) ...... 107 Nozaki D. (GC-05) ...... 236 Ohno H. (CD-06) ...... 96 Oniku O.D. (HG-09) ...... 277 Niimi Y. (DH-10) ...... 141 Nozaki T. (AD-06) ...... 23 Ohno H. (CD-09) ...... 96 Ono K. (AG-11) ...... 32 Niimi Y. (DP-01) ...... 142 Nozaki T. (BS-12) ...... 80 Ohno H. (DC-01) ...... 128 Ono K. (AV-12) ...... 50 Niimi Y. (GC-05) ...... 236 Nozaki T. (CB-11) ...... 92 Ohno H. (DC-09) ...... 129 Ono K. (BF-09) ...... 66 Niimi Y. (GP-11) ...... 250 Nozaki T. (CE-09) ...... 98 Ohno H. (DC-10) ...... 129 Ono K. (BX-05) ...... 89 Niizeki T. (AF-13) ...... 29 Nozaki T. (EH-13) ...... 178 Ohno H. (DH-09) ...... 141 Ono K. (DU-14) ...... 155 Niizeki T. (FP-07) ...... 213 Nozaki T. (EP-16) ...... 180 Ohno H. (FU-07) ...... 224 Ono K. (FF-04) ...... 206 Nikitenko V. (GE-07) ...... 241 Nozaki T. (GU-13) ...... 261 Ohno H. (GT-10) ...... 258 Ono K. (FF-05) ...... 207 Nikitin A.A. (FS-03) ...... 220 Nozaki T. (HA-05) ...... 265 Ohnuki S. (CT-02) ...... 115 Ono K. (FF-07) ...... 207 Nikitin V. (DC-08) ...... 129 Nuzzi D. (FD-03) ...... 203 Ohodnicki P. (BR-10) ...... 78 Ono K. (FF-12) ...... 208 Nikitin V. (GC-09) ...... 236 Ohodnicki P. (CG-04) ...... 102 Ono T. (BB-11) ...... 57 Nikitin V. (GT-11) ...... 258 - O - Ohodnicki P.R. (CG-03) ...... 102 Ono T. (CB-13) ...... 92 Nikonov D. (CP-14) ...... 108 Ohsawa T. (DC-01) ...... 128 Ono T. (DP-10) ...... 144 Nikonov D. (GT-09) ...... 258 O’Brien L. (BB-12) ...... 57 Ohsawa T. (GT-10) ...... 258 Ono T. (DT-15) ...... 153 Nikonov D.E. (CD-08) ...... 96 O’Brien L. (BP-15) ...... 74 Ohshima S. (EV-08) ...... 193 Ono T. (EU-01) ...... 189 Ning X. (FQ-09) ...... 216 O’Brien L. (DB-12) ...... 127 Ohtake M. (AG-14) ...... 32 Ono T. (FE-06) ...... 205 Ning X. (GV-10) ...... 262 O’Brien L. (DD-03) ...... 131 Ohtake M. (AP-02) ...... 35 Ono T. (FU-07) ...... 224 Ning-ning C. (DS-08) ...... 150 O’Grady K. (EP-13) ...... 180 Ohtake M. (DV-08) ...... 157 Onose Y. (XA-03) ...... 17 Nishihara S. (GD-11) ...... 239 O’Grady K. (FH-02) ...... 210 Ohtomo M. (GH-09) ...... 248 Onoue S. (EP-15) ...... 180 Nishimura K. (BS-09) ...... 80 O’Grady K. (FP-09) ...... 213 Ohtori H. (AV-12) ...... 50 Onuki M. (GC-11) ...... 237 Nishimura K. (FU-14) ...... 225 O’Reilly S. (AD-11) ...... 24 Ohtori H. (DC-06) ...... 129 Oogane M. (AC-11) ...... 22 Nishio-Hamane D. (GF-07) ...... 243 O’Reilly S. (DB-11) ...... 127 Ohtsuka M. (BS-13) ...... 80 Oogane M. (CU-06) ...... 118 Nishiuchi T. (FF-03) ...... 206 O’Shea K. (DB-11) ...... 127 Ohtsuka M. (FX-07) ...... 230 Oogane M. (EU-13) ...... 191 Nishiwaki M. (FX-01) ...... 230 O’Sullivan E. (GC-06) ...... 236 Ohtsuki T. (AG-04) ...... 30 Oogane M. (FB-11) ...... 200 Nishiyama K. (CP-05) ...... 107 Oberdick S.D. (BS-15) ...... 81 Oida M. (AD-06) ...... 23 Oogane M. (FX-09) ...... 231 Nishizaki T. (EQ-13) ...... 182 Oberdick S.D. (EE-07) ...... 170 Oida M. (CE-09) ...... 98 Oogane M. (GB-13) ...... 234 Nisoli C. (DD-03) ...... 131 Obi O. (AV-08) ...... 49 Oikawa T. (BF-10) ...... 66 Oogane M. (GB-14) ...... 235 Nistor L.E. (DP-14) ...... 144 Obi O. (DS-02) ...... 149 Oikawa T. (HB-02) ...... 265 Oogane M. (GH-07) ...... 247 Nistor L.E. (GE-12) ...... 242 Obi O. (FV-01) ...... 226 Oikawa T. (HD-09) ...... 271 Oomaru K. (DX-02) ...... 160 Niu E. (GV-04) ...... 261 Obi O. (FV-02) ...... 226 Oka H. (DR-12) ...... 148 Oomiya H. (ET-07) ...... 188 Niu Q. (DH-08) ...... 141 Ocker B. (BS-16) ...... 81 Okabe S. (ER-01) ...... 182 Oosawa K. (FP-05) ...... 213 Niu S. (CT-17) ...... 116 Ocker B. (CU-07) ...... 118 Okada K. (DW-08) ...... 159 Oowada T. (GT-02) ...... 257 Niu S. (CV-04) ...... 120 Ocker B. (HC-06) ...... 268 Okamoto I. (HF-07) ...... 275 Opitz O. (DG-12) ...... 139 Nlebedim C.I. (AW-14) ...... 52 Ockert B. (AG-12) ...... 32 Okamoto K. (DG-05) ...... 138 Oppeneer P. (ED-02) ...... 167 Nlebedim C.I. (CF-01) ...... 99 Ockert B. (BB-04) ...... 55 Okamoto S. (AV-01) ...... 48 Oppeneer P.M. (FB-06) ...... 199 Nlebedim C.I. (CH-09) ...... 105 Ockert B. (FU-10) ...... 225 Okamoto S. (BT-05) ...... 81 Or S. (AS-12) ...... 43 Nlebedim C.I. (HD-11) ...... 271 Odbadrakh K. (DG-13) ...... 139 Okamoto S. (BT-14) ...... 82 Or S. (AT-15) ...... 46 Nobuhara H. (GW-06) ...... 263 Odkhuu D. (GQ-14) ...... 253 Okamoto S. (CT-14) ...... 116 Or S. (DR-03) ...... 147 Nogués J. (CC-09) ...... 94 Oepen H. (DG-07) ...... 139 Okamoto S. (DT-14) ...... 153 Orlowski G. (BH-07) ...... 71 Nogues J. (FP-11) ...... 214 Oepen H. (EA-05) ...... 162 Okamoto S. (DT-15) ...... 153 Orquiz C. (BV-03) ...... 86 Noh H. (CX-05) ...... 123 Oepen H. (ES-14) ...... 186 Okamoto S. (FE-06) ...... 205 Ortiz Pauyac C. (DP-12) ...... 144 Noh H. (EQ-01) ...... 180 Oepen H.P. (DE-07) ...... 134 Okamoto S. (HF-04) ...... 274 Oryoshi M. (EV-09) ...... 193 Nolting F. (CF-09) ...... 100 Ogawa D. (AV-05) ...... 49 Okamoto Y. (GW-06) ...... 263 Osawa H. (GW-06) ...... 263 Nolting F. (DD-01) ...... 130 Ogawa S. (AC-09) ...... 22 Okatov S. (AG-15) ...... 32 Osetskiy Y. (DG-13) ...... 139 Nolting F. (FS-01) ...... 219 Ogawa T. (BW-02) ...... 87 Okatov S. (CD-13) ...... 97 Oshima D. (CT-12) ...... 116 Nomura H. (GT-01) ...... 257 Ogawa T. (HD-09) ...... 271 Oki S. (BP-12) ...... 74 Oshima N. (ET-04) ...... 187 Nomura K. (FP-15) ...... 214 Ogimoto H. (AV-02) ...... 48 Okishio T. (AX-05) ...... 53 Ostler T.A. (BX-07) ...... 89 Nordeen P.K. (GB-06) ...... 233 Ogiwara M. (CU-11) ...... 118 Okubo A. (BS-13) ...... 80 Östman E. (GE-06) ...... 241 Nosegbe D. (BW-10) ...... 88 Ogrin F.Y. (AC-05) ...... 21 Okubo A. (FX-07) ...... 230 Otani Y. (AC-09) ...... 22 Noshiro H. (AS-10) ...... 43 Oh S. (CV-08) ...... 120 Okuda M. (DE-02) ...... 133 Otani Y. (CP-06) ...... 107 Noske M. (BG-06) ...... 68 Oh Y. (AE-06) ...... 26 Okuda M. (DU-04) ...... 154 Otani Y. (DH-10) ...... 141 Noske M. (DB-13) ...... 127 Oh Y. (BS-04) ...... 79 Okuda M. (FU-06) ...... 224 Otani Y. (DP-01) ...... 142 Noske M. (GP-07) ...... 250 Ohdaira Y. (AC-11) ...... 22 Okuyama H. (BS-09) ...... 80 Otani Y. (GC-05) ...... 236 Notin L. (AU-10) ...... 47 Ohdaira Y. (GB-14) ...... 235 Olamit J. (AD-05) ...... 23 Otani Y. (GP-11) ...... 250 Notin L. (BB-07) ...... 56 Ohdo T. (FG-05) ...... 209 Olga K.A. (BW-06) ...... 88 Otori H. (FF-05) ...... 207 Notin L. (BU-09) ...... 84 Ohe J. (AC-01) ...... 20 Olive Méndez S.F. (DV-05) ...... 156 Otsuka Y. (CT-20) ...... 117 Novak P. (CQ-11) ...... 110 Ohishi K. (FP-04) ...... 213 Oliveira G.P. (FS-13) ...... 221 Otsuki H. (BU-03) ...... 83 Novák P. (FF-01) ...... 206 Ohki T. (DP-03) ...... 143 Oliveira L.L. (EW-01) ...... 194 Otsuki H. (FP-03) ...... 213 Novak R. (AU-03) ...... 46 Ohkoshi S. (DV-09) ...... 157 Ollefs K. (AA-03) ...... 17 Otsuki H. (FU-02) ...... 224 Novak R.L. (AU-13) ...... 48 Ohkoshi S. (HD-01) ...... 270 Olmsted P. (DD-02) ...... 130 Ou Z. (CF-12) ...... 101 Novak V. (DP-07) ...... 143 Ohkoshi S. (HD-02) ...... 270 Olsen B. (HE-02) ...... 272 Ou Z.Q. (EF-07) ...... 172 320 PROGRAM PROGRAM 321

Ouazi S. (DE-08) ...... 134 Park J. (FG-13) ...... 210 Peng Y. (DR-08) ...... 148 Pinkerton F. (BF-14) ...... 67 Ouyang H. (EP-10) ...... 179 Park J. (HD-03) ...... 270 Peng Y. (EW-07) ...... 195 Pinkerton F.E. (DF-01) ...... 135 Ouyang J. (AS-11) ...... 43 Park M. (CV-13) ...... 121 Peng Y. (FG-12) ...... 210 Pinkerton F.E. (DF-06) ...... 136 Ouyang J. (GS-04) ...... 256 Park N. (GQ-14) ...... 253 Pennycook S.J. (DE-01) ...... 133 Pinkerton F.E. (GF-10) ...... 244 Ovari A.T. (AR-15) ...... 41 Park S. (AS-02) ...... 42 Pennycook S.J. (EA-02) ...... 162 Pinna D. (CB-03) ...... 91 Ovari T. (DG-04) ...... 138 Park S. (BP-08) ...... 73 Peprah M.K. (FD-08) ...... 203 Pinto A. (AX-07) ...... 53 Ovari T.A. (AR-05) ...... 40 Park S. (BS-07) ...... 80 Peram D. (GS-14) ...... 257 Pinto J. (DU-01) ...... 153 Ovchinnikov A. (GD-11) ...... 239 Park S. (FH-06) ...... 211 Peram D. (HH-08) ...... 279 Piotrowski L. (AW-15) ...... 52 Ovchinnikov S. (DW-07) ...... 159 Park S. (FT-18) ...... 223 Pereira A. (AR-10) ...... 40 Piotrowski S. (HE-04) ...... 272 Ovchinnikov S. (ER-11) ...... 184 Park S. (FT-19) ...... 223 Pereira A.L. (AX-08) ...... 53 Piotrowski S.K. (BS-15) ...... 81 Ovichi M. (CF-13) ...... 101 Park Y. (AR-13) ...... 41 Perera D.N. (EU-05) ...... 190 Piotrowski S.K. (DE-06) ...... 134 Ovichi M. (GQ-15) ...... 253 Park Y. (CV-03) ...... 120 Peressi M. (GH-04) ...... 247 Piquemal J. (AF-11) ...... 29 Oyabu S. (BU-03) ...... 83 Parker D. (AF-12) ...... 29 Peretzki P. (EH-07) ...... 177 Piramanayagam S. (HF-07) ...... 275 Oyabu S. (FP-03) ...... 213 Parker G. (HF-05) ...... 274 Perez Alcazar G. (ER-10) ...... 183 Piramanayagam S.N. (AG-06) ...... 31 Oyabu S. (FU-02) ...... 224 Parkes D. (GB-05) ...... 233 Pérez Alcázar G.A. (ER-06) ...... 183 Piramanayagam S.N. (DU-07) . . . . .154 Ozatay O. (BG-08) ...... 69 Parkes D.E. (BB-05) ...... 56 Perez del Real R. (GE-03) ...... 240 Pires M.M. (FQ-01) ...... 215 Parkes D.E. (CF-04) ...... 99 Pérez G.D. (GQ-07) ...... 252 Pirro P. (AC-11) ...... 22 - P - Parkin S. (BA-02) ...... 54 Perez N. (DE-01) ...... 133 Pisana S. (BT-07) ...... 82 Parkin S. (BB-03) ...... 55 Perez N. (EA-02) ...... 162 Pisana S. (HF-05) ...... 274 Pachauri N. (ED-09) ...... 168 Parkin S. (BD-07) ...... 61 Perna P. (HC-01) ...... 267 Pisani D.M. (GB-06) ...... 233 Padhan P. (CW-03) ...... 121 Parkin S. (CU-01) ...... 117 Perna P. (HC-11) ...... 269 Pistora J. (AT-06) ...... 44 Padilla J. (AE-10) ...... 26 Parkin S. (HH-05) ...... 279 Perron J. (DD-01) ...... 130 Pistora J. (CX-04) ...... 123 Padilla-Pantoja J. (HH-02) ...... 278 Parkin S.S. (DH-06) ...... 140 Persson J. (DC-02) ...... 128 Pistora J. (GD-02) ...... 238 Padmanapan S. (DT-06) ...... 152 Parkin S.S. (GC-06) ...... 236 Pertlik F. (FD-11) ...... 204 Pittala S. (GS-14) ...... 257 Padmanapan S. (EP-09) ...... 179 Parsons R.R. (CG-02) ...... 102 Perzynski R. (DV-10) ...... 157 Piva M.M. (DQ-10) ...... 146 Paduan-Filho A. (CQ-14) ...... 110 Pashkin A. (BD-13) ...... 62 Peters L. (DE-04) ...... 133 Pizzini S. (AU-08) ...... 47 Paesano Jr. A. (EV-11) ...... 193 Pasko A. (AH-06) ...... 33 Petersen D.H. (BS-14) ...... 81 Pizzini S. (AU-14) ...... 48 Paesano Jr. A. (EX-02) ...... 196 Pasquale M. (CC-06) ...... 93 Petersen D.H. (ET-17) ...... 189 Pizzini S. (DB-05) ...... 126 Page K. (FD-07) ...... 203 Patel S.J. (HB-08) ...... 266 Peterson J. (FD-07) ...... 203 Pizzini S. (GE-12) ...... 242 Pagliuso P.G. (AX-08) ...... 53 Patel S.K. (ES-08) ...... 186 Petit D. (BB-12) ...... 57 Pizzocchero F. (ET-17) ...... 189 Pagliuso P.G. (CQ-09) ...... 110 Patel S.K. (ES-09) ...... 186 Petit D. (CC-01) ...... 93 Plekhanov E. (CE-01) ...... 97 Pagliuso P.G. (CS-03) ...... 113 Paterson G. (AD-11) ...... 24 Petit D. (CC-10) ...... 94 Plotnikova E. (HC-05) ...... 268 Pagliuso P.G. (CS-04) ...... 113 Paterson G. (DB-11) ...... 127 Petit D. (ET-10) ...... 188 Plumer M.L. (GW-03) ...... 263 Pagliuso P.G. (CS-05) ...... 114 Pathak A. (DQ-03) ...... 145 Petit D.C. (CC-02) ...... 93 Pogoryelov Y. (DA-01) ...... 124 Pagliuso P.G. (DQ-10) ...... 146 Paudyal D. (BD-01) ...... 60 Petroff F. (DC-11) ...... 129 Poirier E. (DF-01) ...... 135 Pai C. (DH-04) ...... 140 Paudyal D. (DQ-03) ...... 145 Petroff F. (HC-10) ...... 269 Poirier E. (DF-06) ...... 136 Pai C. (FA-01) ...... 197 Paul Boncour V. (DG-11) ...... 139 Petti D. (CE-01) ...... 97 Pokharel G. (BV-08) ...... 86 Pak J. (GE-01) ...... 240 Paul R. (EB-01) ...... 163 Peyrade D. (BH-02) ...... 70 Polikarpov E. (DF-02) ...... 135 Pakala M. (DP-14) ...... 144 Paul S. (AG-13) ...... 32 Pfannes H. (FW-09) ...... 229 Pollard S.D. (EA-03) ...... 162 Pal A. (CE-08) ...... 98 Paula F.L. (DV-10) ...... 157 Pfau B. (BG-02) ...... 68 Pomjakushin V. (AE-10) ...... 26 Pal B. (DC-02) ...... 128 Paulose P.L. (HH-07) ...... 279 Pham H.N. (EW-03) ...... 194 Pomper M. (EW-11) ...... 195 Pal L. (AX-14) ...... 54 Paz E. (AS-09) ...... 42 Phan M. (AQ-02) ...... 37 Pong P. (DX-07) ...... 160 Pal L. (FQ-07) ...... 216 Paz E. (CH-08) ...... 105 Phan M. (AQ-09) ...... 38 Poole A. (AE-11) ...... 27 Pal S. (BU-02) ...... 83 Paz E. (CH-12) ...... 106 Phan M. (AR-12) ...... 41 Poon S. (BE-11) ...... 64 Palma J.L. (AH-08) ...... 34 Paz E. (CH-13) ...... 106 Phan M. (BE-09) ...... 64 Poon S. (HC-12) ...... 269 Palmstrøm C.J. (HB-08) ...... 266 Pearson J. (DU-12) ...... 155 Phan M. (DS-14) ...... 151 Porer M. (BD-13) ...... 62 Palsson G.K. (FC-02) ...... 200 Pearson J. (FP-13) ...... 214 Phan M. (EP-04) ...... 179 Porod W. (BB-02) ...... 55 Palsson G.K. (GE-06) ...... 241 Pearson T. (HE-05) ...... 272 Phan M. (EW-03) ...... 194 Porod W. (BB-14) ...... 57 Panaccione G. (CE-01) ...... 97 Pechan M.J. (EU-02) ...... 189 Phan M. (FQ-03) ...... 215 Porod W. (FP-06) ...... 213 Panaccione G. (ED-03) ...... 167 Pecharsky V.K. (AP-12) ...... 36 Phan M. (GD-07) ...... 238 Porod W. (GT-07) ...... 258 Panagiotopoulos I. (DX-01) ...... 160 Pecharsky V.K. (BD-01) ...... 60 Phan M. (HD-04) ...... 270 Porokhnyuk A. (FG-05) ...... 209 Panchal V. (EA-01) ...... 161 Pecharsky V.K. (DQ-03) ...... 145 Phan M.H. (EF-01) ...... 171 Portemont C. (CD-07) ...... 96 Pandey B. (AP-09) ...... 36 Pecharsky V.K. (DQ-09) ...... 146 Phan M.H. (EQ-03) ...... 181 Porter N. (AB-01) ...... 18 Pandey H. (ET-05) ...... 188 Pecharsky V.K. (EF-10) ...... 172 Phan T. (DW-02) ...... 158 Porter N.A. (GH-03) ...... 247 Pandey H. (ET-16) ...... 189 Pecharsky V.K. (EF-12) ...... 172 Phan T. (FQ-10) ...... 216 Posadas A. (HH-10) ...... 279 Pandey O. (EV-11) ...... 193 Pechnikov V. (BW-05) ...... 87 Phan T. (GU-11) ...... 260 Postava K. (AT-06) ...... 44 Pandya D. (CU-03) ...... 117 Pedrosa S.S. (EW-01) ...... 194 Phan T.L. (EF-01) ...... 171 Potdar S. (HC-09) ...... 268 Pandya D. (FX-06) ...... 230 Peiteado M. (GS-12) ...... 257 Phark S. (DE-08) ...... 134 Potzger K. (GH-14) ...... 248 Pang L. (GD-01) ...... 237 Pelegrini F. (AP-09) ...... 36 Phong P. (DW-02) ...... 158 Poudyal N. (AR-11) ...... 40 Paniago R.M. (FW-09) ...... 229 Pelegrini F. (EP-12) ...... 180 Phuc N. (DW-02) ...... 158 Poudyal N. (BF-11) ...... 67 Pantelides S.T. (DE-01) ...... 133 Pellegrino T. (FH-01) ...... 210 Pi K. (BA-03) ...... 54 Poudyal N. (BH-13) ...... 72 Pantelides S.T. (EA-02) ...... 162 Pellenen A.P. (BF-12) ...... 67 Pi K. (EH-01) ...... 175 Poulin G. (GR-05) ...... 254 Papaioannou E. (EC-11) ...... 166 Peng B. (BU-03) ...... 83 Piamba Jiménez J.F. (ER-06) ...... 183 Prabhakar A. (DS-07) ...... 150 Papp A. (GT-07) ...... 258 Peng B. (FP-03) ...... 213 Piao H. (BU-14) ...... 85 Prabhu D. (ER-09) ...... 183 Parini C. (GG-04) ...... 245 Peng B. (FU-02) ...... 224 Piao H. (GP-09) ...... 250 Prabhu D. (GV-07) ...... 262 Park B. (BS-04) ...... 79 Peng C. (DR-04) ...... 147 Picozzi S. (CE-01) ...... 97 Prabhu Gaunkar N. (CH-09) ...... 105 Park B. (CP-16) ...... 108 Peng H. (FG-01) ...... 208 Picozzi S. (ED-03) ...... 167 Pradhan A.K. (DS-10) ...... 150 Park C. (AX-11) ...... 53 Peng H.X. (AR-12) ...... 41 Piedade M.S. (CH-13) ...... 106 Pramanik T. (EU-10) ...... 191 Park J. (AX-10) ...... 53 Peng H.X. (FQ-03) ...... 215 Pierce D. (CE-04) ...... 98 Pranav Kumar P. (FR-05) ...... 218 Park J. (AX-11) ...... 53 Peng X. (EW-09) ...... 195 Pierre D. (AG-01) ...... 30 Pratapani S. (HD-06) ...... 270 Park J. (CF-05) ...... 99 Peng Y. (BT-08) ...... 82 Pinarbasi M. (GC-08) ...... 236 Pratt A. (AG-02) ...... 30 Park J. (DU-11) ...... 155 Peng Y. (DR-06) ...... 148 Pini M. (CF-03) ...... 99 Preissner C. (AA-05) ...... 18 322 PROGRAM PROGRAM 323

Prejbeanu I. (AD-08) ...... 24 Quarterman P. (DT-16) ...... 153 Ravelosona D. (DU-06) ...... 154 Rivas J. (ED-11) ...... 168 Prejbeanu I. (CD-07) ...... 96 Queiroz Jr. I.S. (EU-14) ...... 191 Ravelosona D. (FU-08) ...... 225 Rivkin K. (AH-13) ...... 34 Prejbeanu L. (AS-08) ...... 42 Quesada A. (FC-12) ...... 202 Ravelosona D. (FU-10) ...... 225 Rivkin K. (FT-07) ...... 222 Prejbeanu L. (AS-14) ...... 43 Quesada A. (FR-02) ...... 217 Ravelosona D. (GT-14) ...... 259 Rizal C. (AT-01) ...... 44 Prejbeanu L.D. (CP-12) ...... 108 Quetz A. (FQ-14) ...... 217 Ravelosona D. (HC-06) ...... 268 Rizzo N.D. (BA-01) ...... 54 Presa B. (FR-08) ...... 218 Quetz A. (GQ-10) ...... 253 Rawat R. (HC-09) ...... 268 Roach L. (EC-09) ...... 166 Prieto J. (GP-05) ...... 249 Quinsat M. (CP-12) ...... 108 Rayan-Serrao C. (EB-01) ...... 163 Robertazzi R.P. (BA-02) ...... 54 Prieto J. (HC-11) ...... 269 Quintero P.A. (FD-08) ...... 203 Razavi F.S. (FD-11) ...... 204 Robertazzi R.P. (GC-06) ...... 236 Prieto J.L. (BC-09) ...... 59 Quispe-Marcatoma J. (AP-09) ...... 36 Read D. (DB-12) ...... 127 Robertson N. (GE-09) ...... 241 Prinsloo A. (CQ-10) ...... 110 Quispe-Marcatoma J. (EP-12) . . . . .180 Read J.C. (GE-09) ...... 241 Robinson J. (BD-09) ...... 61 Prinsloo A.R. (CQ-12) ...... 110 Quitmann C. (BG-01) ...... 67 Rebouças G.O. (EU-14) ...... 191 Roch J. (BB-13) ...... 57 Probert M.I. (FF-09) ...... 207 Reddy V.M. (HD-06) ...... 270 Roch J. (DU-06) ...... 154 Prokopenko O. (CP-03) ...... 107 - R - Redjai Sani S. (EH-02) ...... 176 Roche S. (GD-09) ...... 239 Prokopenko O. (FG-07) ...... 209 Reeve H. (DF-02) ...... 135 Roddick E. (DT-04) ...... 152 Prokscha . (BD-05) ...... 60 Raabe J. (BG-01) ...... 67 Regaieg Y. (CF-15) ...... 101 Rode K. (DH-01) ...... 140 Prost T.E. (AP-12) ...... 36 Raabe J. (BG-02) ...... 68 Register L. (EU-10) ...... 191 Rode K. (ES-07) ...... 185 Provino A. (DQ-02) ...... 145 Raabe J. (FF-07) ...... 207 Regmi R. (FH-04) ...... 211 Rodionova V. (FX-07) ...... 230 Prsa K. (DS-01) ...... 149 Radaelli G. (BE-05) ...... 63 Rehm L. (DP-03) ...... 143 Rodmacq B. (AU-13) ...... 48 Prucnal S. (GH-14) ...... 248 Radaelli G. (CE-01) ...... 97 Reich D. (BH-01) ...... 70 Rodmacq B. (DP-14) ...... 144 Pu Y. (BC-12) ...... 59 Radetinac A. (AE-12) ...... 27 Reichhardt C. (BG-03) ...... 68 Rodmacq B. (GE-12) ...... 242 Pu Y. (BC-13) ...... 59 Radu I. (EU-06) ...... 190 Reid A. (DE-05) ...... 134 Rodmacq B. (HC-01) ...... 267 Pu Y. (CU-08) ...... 118 Radu I. (FB-04) ...... 199 Reid A. (DU-05) ...... 154 Rodrigo C. (HC-11) ...... 269 Pu Y. (GC-02) ...... 235 Radulescu L. (AR-07) ...... 40 Reid A.H. (FB-04) ...... 199 Rodríguez - Páez J.E. (AQ-06) ...... 38 Pufall M.R. (BD-11) ...... 61 Radulov I.A. (EF-03) ...... 171 Reid A.H. (HH-05) ...... 279 Rodriguez Rodriguez C.I. (DV-05) . .156 Pufall M.R. (CP-10) ...... 107 Raghani P. (GH-15) ...... 248 Reid T. (AB-07) ...... 19 Rodríguez V. (BR-09) ...... 78 Puliafito V. (AH-01) ...... 32 Raghavan G. (ER-09) ...... 183 Reig C. (AS-03) ...... 42 Roeser R. (EC-02) ...... 165 Puliafito V. (BG-08) ...... 69 Raghavan G. (GV-07) ...... 262 Reiner J. (BT-07) ...... 82 Rogalev A. (AA-03) ...... 17 Punnoose A. (DW-04) ...... 158 Raghunath G. (CF-02) ...... 99 Reininger R. (GR-01) ...... 253 Rogalev A. (AD-04) ...... 23 Punnoose A. (EQ-11) ...... 182 Raghunath G. (FC-11) ...... 202 Reiss G. (AT-06) ...... 44 Rogalev A. (DH-15) ...... 142 Pushp A. (BA-02) ...... 54 Raghunathan A. (BQ-09) ...... 76 Reiss G. (CH-03) ...... 104 Rogalla H. (BD-11) ...... 61 Ragusa C. (BX-10) ...... 89 Reiss G. (DU-10) ...... 154 Rohart S. (AU-08) ...... 47 - Q - Ragusa C. (ER-15) ...... 184 Reiss G. (EB-04) ...... 163 Rohart S. (AU-13) ...... 48 Rahbar Azad M. (DG-07) ...... 139 Reiss G. (ES-04) ...... 185 Rohart S. (BB-09) ...... 56 Qejvanaj F. (EH-02) ...... 176 Rahim A. (BX-10) ...... 89 Reiss G. (FX-05) ...... 230 Rohart S. (BB-13) ...... 57 Qi B. (HE-05) ...... 272 Rahman B. (DR-06) ...... 148 Reiss G. (GR-02) ...... 254 Rohart S. (DB-05) ...... 126 Qi Y. (AQ-11) ...... 38 Rahman B. (FG-12) ...... 210 Rellinghaus B. (HF-05) ...... 274 Rohart S. (DB-07) ...... 126 Qi Y. (CT-05) ...... 115 Rahman F. (DR-08) ...... 148 Ren W. (DX-09) ...... 161 Rohart S. (DU-06) ...... 154 Qi Y. (EV-13) ...... 193 Rainey K. (EQ-11) ...... 182 Ren X. (DW-09) ...... 159 Rohart S. (HE-07) ...... 273 Qiang Y. (CW-02) ...... 121 Rajaram S. (GT-12) ...... 259 Renucci P. (HB-09) ...... 266 Rojas Sanchez J. (BB-07) ...... 56 Qiang Y. (CW-07) ...... 122 Rajkumar R.K. (EA-01) ...... 161 Ressouche E. (AE-10) ...... 26 Rojas Sanchez J. (BP-14) ...... 74 Qiang Y. (EP-14) ...... 180 Raju M. (CU-03) ...... 117 Retterer S.T. (FP-16) ...... 214 Roldan A. (AS-03) ...... 42 Qiao L. (EV-01) ...... 192 Ralph D. (FA-01) ...... 197 Rettner C. (BB-03) ...... 55 Roldán J. (AS-03) ...... 42 Qin F. (AR-09) ...... 40 Ralph D.C. (DH-04) ...... 140 Rettori A. (CF-03) ...... 99 Roldan M.A. (BE-02) ...... 62 Qin F. (AR-12) ...... 41 Ramanujam B. (GH-15) ...... 248 Rettori C. (AQ-15) ...... 39 Romera M. (EH-15) ...... 178 Qin F. (CG-08) ...... 103 Ramesh R. (EB-01) ...... 163 Rettori C. (AX-08) ...... 53 Romera M. (HC-11) ...... 269 Qin F. (FG-01) ...... 208 Ramesh R. (HA-01) ...... 264 Reyes A.P. (CS-03) ...... 113 Romero J. (CD-10) ...... 96 Qin F. (FQ-03) ...... 215 Ramirez J.G. (CC-04) ...... 93 Reyes Gómez F. (ER-10) ...... 183 Romero J.C. (AB-12) ...... 20 Qin X. (AX-09) ...... 53 Ramos J.E. (AQ-06) ...... 38 Rhee C. (CX-03) ...... 123 Rondinelli J. (DQ-12) ...... 146 Qin X. (CT-05) ...... 115 Ramos P.M. (CH-13) ...... 106 Rhee C. (EQ-01) ...... 180 Ronnow H. (DS-01) ...... 149 Qin X. (GH-06) ...... 247 T.H. (DS-05) ...... 150 Rhensius J. (GB-11) ...... 234 Rosa P. (CS-04) ...... 113 Qiu C. (CR-08) ...... 112 Ranjbar M. (AG-06) ...... 31 Rhensius J.P. (CT-15) ...... 116 Rosa P.F. (CS-05) ...... 114 Qiu C. (CR-09) ...... 112 Ranjbar M. (CU-09) ...... 118 Rhie K. (CD-04) ...... 95 Rosa P.S. (CS-03) ...... 113 Qiu C. (CV-02) ...... 119 Ranjbar M. (EH-02) ...... 176 Riaz S. (FV-08) ...... 227 Rosa P.S. (DQ-10) ...... 146 Qiu C. (CV-15) ...... 121 Ranjbar R. (AP-06) ...... 35 Rice .P. (EW-15) ...... 196 Rosa W.O. (BU-13) ...... 85 Qiu J. (AS-06) ...... 42 Ranzieri P. (CF-08) ...... 100 Rice K. (EE-03) ...... 169 Rosado L. (CH-13) ...... 106 Qiu J. (AU-02) ...... 46 Rao J. (ES-15) ...... 186 Rice P.M. (GC-06) ...... 236 Rosamond M.C. (EC-05) ...... 165 Qiu J. (CR-03) ...... 111 Rao K.V. (GD-13) ...... 239 Richter H. (BT-07) ...... 82 Roschewsky N. (EB-04) ...... 163 Qiu J. (FF-06) ...... 207 Rao, V.N. S. (CT-15) ...... 116 Rick R. (HF-11) ...... 275 Rose V. (AA-05) ...... 18 Qiu J. (FX-08) ...... 231 Rapoport E.A. (BH-06)* ...... 71 Ricolleau C. (AF-11) ...... 29 Rosenman D. (DR-06) ...... 148 Qiu J. (GU-05) ...... 260 Rasing T. (DU-05) ...... 154 Rieger G. (BF-01) ...... 65 Rosenman D. (FG-12) ...... 210 Qiu P. (DS-15) ...... 151 Rasing T. (FB-04) ...... 199 Righi L. (CF-08) ...... 100 Rosenmann D. (AA-05) ...... 18 Qiu X. (AE-13) ...... 27 Ratcliff II W. (AE-11) ...... 27 Riley G.A. (BG-09) ...... 69 Roshchin I.V. (AD-09) ...... 24 Qiu X. (DH-11) ...... 141 Ratcliff W. (AF-10) ...... 29 Rinaldi C. (CE-01) ...... 97 Ross C.A. (AC-04) ...... 21 Qiu X. (GB-11) ...... 234 Ratcliff W. (CE-04) ...... 98 Rinaldi C. (ED-03) ...... 167 Ross C.A. (AE-08) ...... 26 Qiu Z.Q. (AA-04) ...... 18 Ratcliff W.D. (AE-06) ...... 26 Rinaldi M. (CH-05) ...... 105 Ross C.A. (AT-07) ...... 45 Qu D. (DP-11) ...... 144 Rau I.G. (FD-01) ...... 202 Rios N. (AX-07) ...... 53 Ross C.A. (BB-15) ...... 57 Qu D. (EC-07) ...... 166 Rausch T. (FE-07) ...... 205 Rios O. (FV-10) ...... 227 Ross C.A. (DE-09) ...... 134 Qu D. (EC-10) ...... 166 Ravasi T. (FH-03) ...... 211 Rippard W.H. (BD-11) ...... 61 Ross C.A. (DU-08) ...... 154 Qu T. (BC-08) ...... 59 Ravelosona D. (AG-12) ...... 32 Rippard W.H. (CP-10) ...... 107 Ross C.A. (EB-02) ...... 163 Quan C. (FE-03) ...... 204 Ravelosona D. (BB-04) ...... 55 Rissing L. (DG-12) ...... 139 Ross C.A. (EC-02) ...... 165 Quan Z. (AX-09) ...... 53 Ravelosona D. (BB-13) ...... 57 Ritter C. (HH-02) ...... 278 Ross C.A. (EQ-09) ...... 181 Quang T.V. (CQ-08) ...... 110 Ravelosona D. (BS-16) ...... 81 Ritzmann U. (EC-02) ...... 165 Ross C.A. (EU-02) ...... 189 324 PROGRAM PROGRAM 325

Ross C.A. (FU-11) ...... 225 Sagar J. (AD-13) ...... 25 Sampaio L.C. (AX-07) ...... 53 Savero Torres W. (AU-10) ...... 47 Ross C.A. (GD-05) ...... 238 Sagar J. (FX-10) ...... 231 Sampathkumaran E.V. (DS-04) . . . .149 Savero Torres W. (BB-07) ...... 56 Ross C.A. (GE-11) ...... 241 Sagara N. (GD-05) ...... 238 Sampathkumaran E.V. (HH-07) . . . .279 Savero Torres W. (BP-14) ...... 74 Ross C.A. (GP-12) ...... 250 Sagayama R. (BF-09) ...... 66 San Emeterio Alvarez L. (DP-14) . . .144 Savero Torres W. (BU-09) ...... 84 Rössler U. (DD-11) ...... 132 Sagayama R. (FF-05) ...... 207 Sanai T. (AB-10) ...... 19 Saw A. (GE-06) ...... 241 Rott K. (DU-10) ...... 154 Sagnes I. (HB-09) ...... 266 Sanai T. (GD-08) ...... 238 Sawatzki S. (BF-07) ...... 66 Rott K. (EB-04) ...... 163 Saha S. (BU-11) ...... 84 Sanches F. (CP-04) ...... 107 Saxena A. (BG-03) ...... 68 Rougemaille N. (AU-14) ...... 48 Sahashi M. (AD-06) ...... 23 Sanches F. (DA-05) ...... 125 Saxena R.N. (DQ-01) ...... 145 Rougemaille N. (DB-03) ...... 126 Sahashi M. (AP-17) ...... 37 Sánchez A. (FP-11) ...... 214 Saxena R.N. (DQ-07) ...... 145 Rougemaille N. (FC-05) ...... 201 Sahashi M. (CE-09) ...... 98 Sánchez F. (BE-05) ...... 63 Sayeef S. (DH-03) ...... 140 Rousseau J. (AW-05) ...... 51 Sahashi M. (EB-10) ...... 164 Sanchez F. (FC-10) ...... 202 Sbiaa R. (AG-06) ...... 31 Rousseou O. (AC-09) ...... 22 Sahashi M. (EP-16) ...... 180 Sanchez Llamazares J.L. (GQ-07) . .252 Scarfato A. (DU-13) ...... 155 Rout P.K. (ET-05) ...... 188 Sahashi M. (GU-06) ...... 260 Sanchez-Hanke C. (BE-08) ...... 63 Schabes M. (EE-02) ...... 169 Rout P.K. (ET-16) ...... 189 Sahin C. (GH-13) ...... 248 Sánchez-Llamazares J. (EF-15) . . . .173 Schabes M.E. (CT-08) ...... 116 Rowan-Weetaluktuk W.N. (DQ-11) .146 Sahoo A. (DC-02) ...... 128 Sander D. (DE-08) ...... 134 Schabes M.E. (HF-03) ...... 274 Roy K. (GT-05) ...... 258 Saito H. (AB-03) ...... 18 Sanders T. (BE-10) ...... 64 Schaefer R. (EA-04) ...... 162 Roy P. (EF-07) ...... 172 Saito H. (FC-08) ...... 201 Sanders T.D. (EQ-10) ...... 182 Schäfer H. (BD-13) ...... 62 Roy S. (BE-08) ...... 63 Saito H. (FS-15) ...... 221 Sandhu G. (BA-02) ...... 54 Schafer S. (DC-08) ...... 129 Roy S. (BG-13) ...... 70 Saito H. (HB-05) ...... 266 Sandhu G. (GC-06) ...... 236 Schäfer S. (GT-11) ...... 258 Roy U. (EU-10) ...... 191 Saito K. (AB-04) ...... 19 Sando D. (AE-02) ...... 25 Schaffert S. (BG-02) ...... 68 Ruan J. (CR-05) ...... 111 Saito K. (BF-09) ...... 66 Sandoval S.M. (EF-08) ...... 172 Schaltz E. (EG-03) ...... 173 Ruan J. (GR-11) ...... 255 Saito K. (BP-13) ...... 74 Sangalli D. (BE-13) ...... 64 Schellekens A.J. (BB-06) ...... 56 Rudolf D. (EU-08) ...... 190 Saito K. (FF-05) ...... 207 Sani S. (EH-05) ...... 176 Schellekens A.J. (FB-02) ...... 198 Rudolf D. (FB-05) ...... 199 Saito K. (FF-12) ...... 208 Sani S.R. (CB-05) ...... 91 Scherz A. (DE-05) ...... 134 Rui W. (AE-13) ...... 27 Saito S. (BT-02) ...... 81 Sani S.R. (CP-02) ...... 106 Scherz A. (DU-05) ...... 154 Rui W. (ET-02) ...... 187 Saito S. (HF-09) ...... 275 Sani S.R. (DA-01) ...... 124 Scherz A. (FB-04) ...... 199 Ruiz R. (EE-02) ...... 169 Saito T. (DF-09) ...... 136 Sani S.R. (EH-10) ...... 177 Scherz A. (HF-11) ...... 275 Ruotolo A. (BD-09) ...... 61 Saito T. (GF-07) ...... 243 Sankar V.K. (GE-10) ...... 241 Scheunert G. (ET-13) ...... 188 Ruotolo A. (EQ-12) ...... 182 Saito Y. (AX-06) ...... 53 Santamaria J. (BD-08) ...... 61 Schiffer P. (DD-03) ...... 131 Rushforth A.W. (BB-05) ...... 56 Saito Y. (HB-04) ...... 265 Santava E. (CQ-11) ...... 110 Schilling M. (BH-03) ...... 71 Rushforth A.W. (CF-04) ...... 99 Saitoh E. (AC-01) ...... 20 Santhosh P.N. (CQ-02) ...... 109 Schleizer S. (EA-05) ...... 162 Rushforth A.W. (GB-05) ...... 233 Saitoh E. (BP-11) ...... 74 Santhosh P.N. (CS-11) ...... 114 Schlenhoff A. (GB-08) ...... 234 Russek S. (EE-03) ...... 169 Saitoh E. (EC-06) ...... 166 Santillán Rodríguez C.R. (BQ-10) . . .76 Schlenhoff A. (GC-13) ...... 237 Russek S. (FH-11) ...... 212 Saitoh Y. (AB-10) ...... 19 Santos Burgos B. (DB-03) ...... 126 Schlepütz C. (DQ-12) ...... 146 Russek S.E. (BD-11) ...... 61 Saitoh Y. (DT-07) ...... 152 Santos Burgos B. (FC-05) ...... 201 Schlotter W.F. (FB-04) ...... 199 Russek S.E. (CH-10) ...... 105 Saitovitch H. (DQ-01) ...... 145 Santos M.S. (EX-03) ...... 196 Schmalhorst J.M. (FX-05) ...... 230 Russek S.E. (EW-15) ...... 196 Sakaguchi K. (AT-09) ...... 45 Santos R. (ER-03) ...... 183 Schmid A.K. (FC-12) ...... 202 Rusydi A. (DH-11) ...... 141 Sakai H. (HF-08) ...... 275 Santos T. (BT-07) ...... 82 Schmidt G. (CA-05) ...... 90 Ruthramurthy B. (DW-03) ...... 158 Sakai K. (GR-06) ...... 254 Santucci J. (FT-09) ...... 222 Schmitt J. (BE-04) ...... 63 Ryan D. (DQ-11) ...... 146 Sakai S. (GH-09) ...... 248 Sanyadanam S. (GS-14) ...... 257 Schmitt-Landsiedel D. (BB-14) . . . . .57 Ryan D. (EF-10) ...... 172 Sakamaki M. (DT-07) ...... 152 Sanyadanam S. (HH-08) ...... 279 Schmitt-Landsiedel D. (BQ-12) . . . . .76 Ryan D.H. (CS-06) ...... 114 Sakata O. (CQ-05) ...... 109 Sanyal B. (DE-04) ...... 133 Schmitt-Landsiedel D. (HG-06) . . . .277 Ryan P. (AE-04) ...... 26 Sakharov V.K. (DR-05) ...... 148 Saravanan P. (BR-06) ...... 77 Schmool D. (AD-11) ...... 24 Ryan P.J. (FC-04) ...... 201 Sakimura N. (CD-06) ...... 96 Saravanan P. (DT-03) ...... 151 Schneider C.M. (EU-08) ...... 190 Ryan P.J. (HB-06) ...... 266 Sakimura N. (CD-09) ...... 96 Saravanan P. (EP-03) ...... 178 Schneider C.M. (EU-11) ...... 191 Ryiz P.V. (GF-11) ...... 244 Sakuma A. (AV-04) ...... 49 Saravanan P. (HC-04) ...... 268 Schneider C.M. (FB-05) ...... 199 Ryiz P.V. (HG-09) ...... 277 Sakuma A. (CD-01) ...... 95 Sarkar S. (HH-04) ...... 278 Schneider C.M. (FC-02) ...... 200 Ryu G. (CV-08) ...... 120 Sakuma A. (EB-09) ...... 164 Sarma D.D. (DC-02) ...... 128 Schneider C.M. (GH-01) ...... 246 Sakuma A. (EU-04) ...... 190 Saruya T. (GU-04) ...... 259 Schneider M. (BG-02) ...... 68 - S - Sakuraba Y. (AB-04) ...... 19 Saruya T. (HA-05) ...... 265 Schneider M.L. (BA-01) ...... 54 Sakuraba Y. (BP-13) ...... 74 Sasada I. (GG-09) ...... 246 Schneider W. (BC-02) ...... 58 Saari M.M. (GR-06) ...... 254 Salafranca J. (DE-01) ...... 133 Sasaki K. (CT-06) ...... 115 Schoenthal W. (GD-12) ...... 239 Sabino M. (EH-06) ...... 176 Salafranca J. (EA-02) ...... 162 Sasaki M. (HH-06) ...... 279 Scholl A. (DD-01) ...... 130 Sabino M.G. (BC-03) ...... 58 Salazar-Aravena D. (DX-04) ...... 160 Sasaki T. (HB-02) ...... 265 Scholl A. (FC-03) ...... 201 Sabirianov R. (DS-05) ...... 150 Salem M.S. (GP-14) ...... 250 Sassine G. (HG-03) ...... 276 Scholl A. (HH-04) ...... 278 Sabirianov R. (EC-08) ...... 166 Salles B.R. (CE-01) ...... 97 Sato A. (GR-07) ...... 254 Schopphoven C. (DE-03) ...... 133 Sabirianov R. (GQ-10) ...... 253 Salman . (BD-05) ...... 60 Sato F. (CR-10) ...... 112 Schrefl T. (BF-01) ...... 65 Sabirianov R. (GV-11) ...... 262 Sam A. (FE-07) ...... 205 Sato F. (CR-11) ...... 112 Schrefl T. (BX-08) ...... 89 Sabon P. (AS-08) ...... 42 Samal D. (DD-07) ...... 131 Sato H. (BS-02) ...... 79 Schrefl T. (CT-08) ...... 116 Sabon P. (AS-14) ...... 43 Samant M. (BD-07) ...... 61 Sato H. (CD-05) ...... 95 Schrefl T. (FF-09) ...... 207 Sabon P. (BH-02) ...... 70 Samant M. (HH-05) ...... 279 Sato H. (DC-09) ...... 129 Schrefl T. (FF-10) ...... 207 Sabon P. (FH-10) ...... 212 Samanta T. (FQ-14) ...... 217 Sato H. (DC-10) ...... 129 Schubert E. (BQ-15) ...... 76 Sacilottic M. (AX-07) ...... 53 Samanta T. (GQ-10) ...... 253 Sato H. (DH-09) ...... 141 Schuetz G. (BG-06) ...... 68 Sacuto A. (AE-09) ...... 26 Samardak A. (BW-05) ...... 87 Sato H. (ED-09) ...... 168 Schuetz G. (GP-07) ...... 250 Sadano A. (AX-05) ...... 53 Samarin S. (AC-02) ...... 20 Sato M. (AQ-12) ...... 38 Schuhl A. (AU-08) ...... 47 Saemma G. (HF-08) ...... 275 Samarin S. (ET-04) ...... 187 Sato R. (FT-01) ...... 221 Schuhmann H. (EH-07) ...... 177 Saenz J.J. (FC-09) ...... 201 Samin A. (FF-06) ...... 207 Sato R. (FT-02) ...... 222 Schuller I. (AD-10) ...... 24 Saerbeck T. (AD-10) ...... 24 Sampaio . (AU-03) ...... 46 Sato S. (DT-01) ...... 151 Schuller I.K. (CC-04) ...... 93 Safeer C.K. (AE-03) ...... 25 Sampaio J. (BB-09) ...... 56 Sato S. (DT-02) ...... 151 Schultheiss H. (BC-02) ...... 58 Safonov V. (DP-04) ...... 143 Sampaio J. (CB-01) ...... 91 Sato T. (CR-11) ...... 112 Schultz L. (BF-07) ...... 66 Safranski C. (BD-10) ...... 61 Sampaio J. (FU-14) ...... 225 Sato T. (DX-02) ...... 160 Schultz L. (HF-05) ...... 274 Safronov A.P. (GG-02) ...... 245 Sampaio J. (HE-07) ...... 273 Sato Y. (EP-16) ...... 180 Schulz A. (FD-11) ...... 204 326 PROGRAM PROGRAM 327

Schulz T. (BG-02) ...... 68 Shahosseini I. (HG-03) ...... 276 Shi J. (CD-12) ...... 96 Shiratsuchi Y. (EP-15) ...... 180 Schumacher H. (DX-06) ...... 160 Shanmugam J. (EE-08) ...... 170 Shi J. (DH-14) ...... 142 Shiroyama T. (BT-13) ...... 82 Schumacher H.W. (DU-10) ...... 154 Shao B. (AT-11) ...... 45 Shi J. (EC-03) ...... 165 Shirsath S.E. (DV-11) ...... 157 Schumacher H.W. (FU-05) ...... 224 Shao B. (AT-12) ...... 45 Shi Y. (HB-11) ...... 267 Shirsath S.E. (EX-04) ...... 196 Schütz G. (AC-12) ...... 22 Shao B. (CQ-04) ...... 109 Shi Y. (HH-01) ...... 278 Shishido T. (BD-03) ...... 60 Schütz G. (BW-09) ...... 88 Shao B. (FS-14) ...... 221 Shield J. (BF-13) ...... 67 Shishkin D. (FQ-05) ...... 215 Schütz G. (DB-13) ...... 127 Shao Q. (EQ-12) ...... 182 Shield J. (DF-13) ...... 137 Shiu H. (DC-12) ...... 130 Schütz G. (DF-05) ...... 136 Shao W. (BR-08) ...... 78 Shield J. (GF-09) ...... 243 Shiva A. (AT-08) ...... 45 Schütz G. (HE-12) ...... 273 Shao W. (DS-11) ...... 150 Shield J. (GF-10) ...... 244 Shoji T. (AV-12) ...... 50 Schwarzacher W. (DE-02) ...... 133 Shao X. (EG-13) ...... 175 Shield J.E. (CG-10) ...... 103 Shoji T. (FF-04) ...... 206 Schweins R. (BF-06) ...... 66 Shao Y. (EF-05) ...... 171 Shield J.E. (DF-03) ...... 135 Shoji T. (FF-05) ...... 207 Searson P. (EW-11) ...... 195 Sharad M. (GT-05) ...... 258 Shield J.E. (DF-10) ...... 137 Shoji T. (FF-07) ...... 207 Sebastian T. (AC-11) ...... 22 Sharath U.S. (AF-09) ...... 28 Shield J.E. (DF-11) ...... 137 Shoji T. (FF-12) ...... 208 Seehra M. (CS-13) ...... 115 Sharma A. (BH-07) ...... 71 Shield J.E. (FV-02) ...... 226 Shu M. (HF-11) ...... 275 Seelam U.M. (GF-01) ...... 242 Sharma A. (FE-08) ...... 205 Shield J.E. (FV-12) ...... 228 Shubin Y.V. (DV-03) ...... 156 Sefrioui Z. (BD-08) ...... 61 Sharma A. (GS-10) ...... 256 Shield J.E. (GF-12) ...... 244 Shueh C. (EP-08) ...... 179 Seibt M. (EH-07) ...... 177 Sharma J. (ES-08) ...... 186 Shield J.E. (HE-09) ...... 273 Shull R. (CE-04) ...... 98 Seinige H. (CU-02) ...... 117 Sharma J. (ES-09) ...... 186 Shih C. (EP-11) ...... 179 Shull R. (GE-07) ...... 241 Seino T. (BS-09) ...... 80 Sharma M. (BE-04) ...... 63 Shih C. (FQ-09) ...... 216 Shull R.D. (BS-06) ...... 79 Seki S. (GA-02) ...... 232 Sharma M. (DR-07) ...... 148 Shih C. (GV-10) ...... 262 Shull R.D. (DE-03) ...... 133 Seki T. (BP-01) ...... 72 Sharma P. (AR-02) ...... 39 Shih C.W. (BR-02) ...... 77 ShunQuan L. (ES-05) ...... 185 Seki T. (CU-11) ...... 118 Sharma P. (CG-05) ...... 102 Shih C.W. (GV-14) ...... 263 ShunQuan L. (FX-02) ...... 230 Seki T. (FE-09) ...... 205 Sharma P. (DG-04) ...... 138 Shikoh E. (DP-02) ...... 143 Shuto Y. (AX-05) ...... 53 Sekino N. (DR-12) ...... 148 Sharma P. (EV-11) ...... 193 Shim H. (CS-13) ...... 115 Shuto Y. (GT-06) ...... 258 Selberherr S. (EH-04) ...... 176 Sharma R. (EU-09) ...... 190 Shim J. (BU-14) ...... 85 Shuvaeva E. (AR-08) ...... 40 Selberherr S. (HB-03) ...... 265 Shatruk M. (GD-07) ...... 238 Shim J. (GP-09) ...... 250 Shuvaeva E. (CG-09) ...... 103 Sellmyer D. (BF-13) ...... 67 Shaw J. (EE-03) ...... 169 Shima T. (AF-09) ...... 28 Shyu J. (AG-09) ...... 31 Sellmyer D. (DF-12) ...... 137 Shaw J. (FB-05) ...... 199 Shimada T. (GU-09) ...... 260 Si P. (GV-01) ...... 261 Sellmyer D. (DF-13) ...... 137 Shaw J.M. (BC-05) ...... 58 Shimada Y. (DU-02) ...... 153 Sicard L. (CF-15) ...... 101 Sellmyer D.J. (AT-13) ...... 45 Shaw J.M. (BC-07) ...... 59 Shimatsu T. (BT-05) ...... 81 Sichel-Tissot R. (DQ-12) ...... 146 Sellmyer D.J. (BF-04) ...... 65 Shaw J.M. (CC-07) ...... 94 Shimatsu T. (BT-14) ...... 82 Sicot M. (HE-12) ...... 273 Sellmyer D.J. (BQ-15) ...... 76 Shaw J.M. (EU-08) ...... 190 Shimatsu T. (CT-14) ...... 116 Siddharth Rao V. (BT-12) ...... 82 Sellmyer D.J. (BT-16) ...... 83 Sheets A. (BV-02) ...... 85 Shimatsu T. (DT-14) ...... 153 Siddiqui S.A. (BB-15) ...... 57 Sellmyer D.J. (CH-06) ...... 105 Shelford L. (FB-10) ...... 200 Shimatsu T. (DT-15) ...... 153 Siddiqui S.A. (GE-11) ...... 241 Sellmyer D.J. (CH-10) ...... 105 Shelford L.R. (CF-04) ...... 99 Shimatsu T. (FE-06) ...... 205 Siegrist T.M. (GV-09) ...... 262 Sellmyer D.J. (DD-10) ...... 132 Shen B. (BV-05) ...... 86 Shimatsu T. (HF-04) ...... 274 Sierra J.F. (CP-12) ...... 108 Sellmyer D.J. (DF-11) ...... 137 Shen B. (BV-06) ...... 86 Shimidzu N. (FP-04) ...... 213 Sikola T. (GP-03) ...... 249 Sellmyer D.J. (DF-15) ...... 137 Shen B. (CG-13) ...... 103 Shimizu H. (BP-13) ...... 74 Silva A. (AU-03) ...... 46 Sellmyer D.J. (FV-12) ...... 228 Shen B. (EF-11) ...... 172 Shimokawa T. (BR-12) ...... 78 Silva A.V. (AS-09) ...... 42 Sellmyer D.J. (HF-02) ...... 274 Shen B. (EG-13) ...... 175 Shimokawa T. (DG-06) ...... 138 Silva T. (EE-03) ...... 169 Selomulya C. (DW-10) ...... 159 Shen B. (EQ-04) ...... 181 Shimomura N. (CE-09) ...... 98 Silva T. (FB-05) ...... 199 Semenov A.A. (FS-03) ...... 220 Shen B. (EQ-06) ...... 181 Shimomura N. (CP-05) ...... 107 Silva T.J. (BC-05) ...... 58 Sen S. (AH-09) ...... 34 Shen B. (FQ-04) ...... 215 Shimomura N. (EP-16) ...... 180 Silva T.J. (BC-07) ...... 59 Sen S. (GD-10) ...... 239 Shen B. (FQ-08) ...... 216 Shimon G. (AC-04) ...... 21 Silva T.J. (CC-07) ...... 94 Senapati K. (CE-08) ...... 98 Shen B. (GQ-06) ...... 252 Shimon G. (GP-12) ...... 250 Silva T.J. (DA-02) ...... 124 Seneor P. (DC-11) ...... 129 Shen B. (GV-04) ...... 261 Shin H. (CV-01) ...... 119 Silva T.J. (EU-08) ...... 190 Seneor P. (HC-10) ...... 269 Shen H. (AR-09) ...... 40 Shin H. (CV-13) ...... 121 Silva T.J. (EW-15) ...... 196 Seo H. (DG-09) ...... 139 Shen H. (CG-08) ...... 103 Shin J. (AS-07) ...... 42 Silva Valencia J. (DQ-05) ...... 145 Seo M. (AS-02) ...... 42 Shen H. (CS-08) ...... 114 Shin K. (CD-04) ...... 95 Silveyra J.M. (ER-14) ...... 184 Seo M. (BP-08) ...... 73 Shen H. (FR-13) ...... 219 Shin K. (FU-09) ...... 225 Sim C. (BC-03) ...... 58 Seo S. (CP-13) ...... 108 Shen H. (FR-15) ...... 219 Shin K. (FU-15) ...... 226 Sim C. (EH-06) ...... 176 Sepehri-Amin H. (FF-11) ...... 208 Shen J. (CH-10) ...... 105 Shin K. (GS-05) ...... 256 Simões A.Z. (GS-08) ...... 256 Sepehri-Amin H. (FV-11) ...... 227 Shen J. (EF-11) ...... 172 Shin S. (CP-16) ...... 108 Singh A. (AH-12) ...... 34 Sepehri-Amin H. (GF-13) ...... 244 Shen J. (GS-01) ...... 255 Shin S. (CU-01) ...... 117 Singh A. (CD-13) ...... 97 Serga A.A. (AC-08) ...... 21 Shen K. (AG-09) ...... 31 Shin Y. (ES-11) ...... 186 Singh A. (GT-08) ...... 258 Serga A.A. (AC-11) ...... 22 Shen S. (CG-03) ...... 102 Shinde V.S. (DV-11) ...... 157 Singh B. (GU-01) ...... 259 Sergelius P. (GP-14) ...... 250 Shen S. (ET-11) ...... 188 Shindou R. (AC-01) ...... 20 Singh D.J. (AF-12) ...... 29 Serna C.J. (DE-01) ...... 133 Shen S. (FT-12) ...... 222 Shinjo T. (CP-01) ...... 106 Singh G. (AQ-08) ...... 38 Serpico C. (AH-06) ...... 33 Shen Y. (BV-02) ...... 85 Shinjo T. (DP-02) ...... 143 Singh G. (CQ-16) ...... 111 Serpico C. (DP-09) ...... 143 Sheng Y. (AE-13) ...... 27 Shinjo T. (GB-02) ...... 233 Singh G. (FS-04) ...... 220 Serrano A. (FC-12) ...... 202 Shepherd D. (BX-02) ...... 88 Shinjo T. (HA-05) ...... 265 Singh J. (HC-08) ...... 268 Serrano R.L. (DQ-13) ...... 146 Sheppard C.J. (CQ-10) ...... 110 Shinjo T. (HB-02) ...... 265 Singh K. (DS-04) ...... 149 Serrano-Guisan S. (CH-12) ...... 106 Sheppard C.J. (CQ-12) ...... 110 Shinoda K. (AF-11) ...... 29 Singh K. (GS-10) ...... 256 Serrano-Ramon L.E. (BB-12) ...... 57 Sherman S.G. (FW-04) ...... 228 Shiokawa Y. (AP-17) ...... 37 Singh K. (HH-07) ...... 279 Seto Y. (BT-04) ...... 81 Shestra M. (FD-07) ...... 203 Shiomi Y. (BP-11) ...... 74 Singh M.K. (CQ-16) ...... 111 Seu K.A. (BG-13) ...... 70 Shi D. (DD-02) ...... 130 Shiota Y. (GB-02) ...... 233 Singh M.K. (FS-04) ...... 220 Seyoum H.M. (CF-13) ...... 101 Shi D. (DV-02) ...... 156 Shiota Y. (HA-05) ...... 265 Singh N. (GE-04) ...... 240 Shabadi V. (AE-12) ...... 27 Shi F. (EP-02) ...... 178 Shirai M. (CQ-05) ...... 109 Singh N.K. (DQ-09) ...... 146 Shah F. (FP-06) ...... 213 Shi F. (FX-03) ...... 230 Shiraishi M. (DP-02) ...... 143 Singh N.K. (EF-12) ...... 172 Shah F.A. (GE-10) ...... 241 Shi F. (GH-05) ...... 247 Shiraishi M. (HB-01) ...... 265 Singh S. (BE-02) ...... 62 Shah I. (FR-14) ...... 219 Shi H. (CU-12) ...... 119 Shiraishi M. (HB-02) ...... 265 Singh V. (GD-05) ...... 238 Shah V.R. (AT-13) ...... 45 Shi J. (AQ-13) ...... 39 Shirato N. (AA-05) ...... 18 Sinha J. (AG-11) ...... 32 328 PROGRAM PROGRAM 329

Sinha P. (AB-01) ...... 18 Sohn J. (CP-16) ...... 108 Stamenov P. (AB-06) ...... 19 Stusser N. (DG-11) ...... 139 Sinha P. (GH-03) ...... 247 Sohn J. (CU-01) ...... 117 Stamenov P.S. (ES-07) ...... 185 Su H. (AP-16) ...... 37 Sinha S.K. (BG-13) ...... 70 Sokalski V. (BR-10) ...... 78 Stamm C. (AA-02) ...... 17 Su H. (EX-07) ...... 197 Sinko M. (EU-02) ...... 189 Sokalski V. (FU-12) ...... 225 Stampe P.A. (EQ-08) ...... 181 Su H. (FP-15) ...... 214 Sinova J. (DP-07) ...... 143 Sokalski V.M. (BS-03) ...... 79 Stamps R. (AC-13) ...... 22 Su H. (HF-10) ...... 275 Sinova J. (XA-01) ...... 17 Sokolov A. (GQ-10) ...... 253 Stamps R. (AD-11) ...... 24 Su Z. (CX-06) ...... 123 Siracusano G. (BX-04) ...... 89 Solanki A.K. (FD-06) ...... 203 Stamps R. (BC-06) ...... 58 Su Z. (CX-09) ...... 123 Siroky P. (CX-04) ...... 123 Soledade P. (AU-03) ...... 46 Stamps R. (DB-11) ...... 127 Subramanian V. (CS-11) ...... 114 Siroky P. (GD-02) ...... 238 Sommacal M. (DA-02) ...... 124 Stamps R.L. (AU-13) ...... 48 Suemasu T. (AB-10) ...... 19 Sirotkin E. (AC-05) ...... 21 Sommer R.L. (BU-13) ...... 85 Stamps R.L. (CB-02) ...... 91 Suemasu T. (GD-08) ...... 238 Sirvent P. (FR-02) ...... 217 Somodi K.A. (FD-08) ...... 203 Stamps R.L. (CC-03) ...... 93 Suemoto T. (HD-01) ...... 270 Siu Z. (BP-09) ...... 73 Sondezi B.M. (DQ-06) ...... 145 Stancu A. (AT-04) ...... 44 Suenaga S. (DG-05) ...... 138 Sivakumar C. (CD-13) ...... 97 Song H. (AW-03) ...... 50 Stancu A. (BQ-04) ...... 75 Suess D. (HF-12) ...... 275 Sizeland J. (AX-03) ...... 52 Song H. (CP-16) ...... 108 Stancu A. (BQ-05) ...... 75 Suess D. (HG-01) ...... 276 Sizeland J. (GH-02) ...... 246 Song H. (CU-01) ...... 117 Stancu A. (BU-12) ...... 84 Suetsuna T. (DG-05) ...... 138 Sklenar J. (AQ-04) ...... 38 Song J. (CD-04) ...... 95 Stancu A. (CR-04) ...... 111 Sugahara S. (AX-05) ...... 53 Sklenar J. (BC-04) ...... 58 Song J. (ET-14) ...... 189 Stancu A. (DX-01) ...... 160 Sugahara S. (GT-06) ...... 258 Sklenar J. (CB-08) ...... 92 Song M. (BD-07) ...... 61 Stancu A. (EW-02) ...... 194 Sugawara Y. (FS-15) ...... 221 Sklenar J. (DD-06) ...... 131 Song M. (DR-11) ...... 148 Stancu A. (FD-04) ...... 203 Sugibayashi T. (CD-06) ...... 96 Skokov K. (CF-14) ...... 101 Song N. (DW-09) ...... 159 Stankiewicz A.A. (FT-08) ...... 222 Sugibayashi T. (CD-09) ...... 96 Skokov K. (DF-08) ...... 136 Song W. (DQ-08) ...... 146 Stanley D. (EU-02) ...... 189 Sugihara A. (CD-01) ...... 95 Skokov K.P. (BF-12) ...... 67 Song Y. (BC-02) ...... 58 Starchikov S. (ER-11) ...... 184 Sugihara A. (EU-04) ...... 190 Skokov K.P. (EF-03) ...... 171 Song Y. (BP-16) ...... 74 Starr J. (CG-06) ...... 102 Sugii T. (AS-10) ...... 43 Skomski R. (AF-05) ...... 28 Song Z. (CV-14) ...... 121 Stasiak J. (AW-03) ...... 50 Sugimoto S. (GP-11) ...... 250 Skomski R. (AF-10) ...... 29 Song Z. (GV-08) ...... 262 Stavis S.M. (GR-13) ...... 255 Sugita R. (DT-01) ...... 151 Skomski R. (AT-13) ...... 45 Sonntag A. (GB-08) ...... 234 Steadman P. (GP-16) ...... 251 Sugita R. (DT-02) ...... 151 Skomski R. (BF-04) ...... 65 Sonntag A. (GC-13) ...... 237 Steentjes S. (BQ-11) ...... 76 Sugiyama H. (AX-06) ...... 53 Skomski R. (BF-13) ...... 67 Sonobe Y. (BS-08) ...... 80 Stefanowicz W. (GE-12) ...... 242 Sugiyama H. (HB-04) ...... 265 Skomski R. (BQ-15) ...... 76 Sort J. (FP-11) ...... 214 Steil D. (GD-01) ...... 237 Sugiyama T. (AB-04) ...... 19 Skomski R. (CH-06) ...... 105 Soumiya T. (FX-01) ...... 230 Stein A. (DD-02) ...... 130 Sugiyama T. (CS-01) ...... 113 Skomski R. (CH-10) ...... 105 Sousa M.A. (EP-12) ...... 180 Stein A. (DD-05) ...... 131 Sui Y. (CV-07) ...... 120 Skomski R. (DD-10) ...... 132 Sousa R.C. (DP-14) ...... 144 Stein D.L. (CB-03) ...... 91 Sukegawa H. (AB-09) ...... 19 Skomski R. (DF-11) ...... 137 Souza C.M. (EW-01) ...... 194 Stein F. (DB-02) ...... 125 Sukegawa H. (AG-03) ...... 30 Skomski R. (DF-13) ...... 137 Souza-Neto N. (CQ-07) ...... 109 Steinhoff U. (EW-12) ...... 195 Sukegawa H. (CP-06) ...... 107 Skomski R. (DF-15) ...... 137 Spahr H. (DG-07) ...... 139 Steinke N.J. (CC-10) ...... 94 Sukegawa H. (DC-05) ...... 128 Skomski R. (DS-07) ...... 150 Sparks P.D. (ES-08) ...... 186 Stepankova H. (CX-04) ...... 123 Sukegawa H. (DH-10) ...... 141 Skomski R. (FD-06) ...... 203 Sparks P.D. (ES-09) ...... 186 Sterbinsky G.E. (FV-04) ...... 227 Sukegawa H. (GT-06) ...... 258 Skomski R. (FV-12) ...... 228 Spencer J. (AW-03) ...... 50 Sterwerf C. (FX-05) ...... 230 Sukovatitsina E. (BW-05) ...... 87 Skoropata E. (AD-09) ...... 24 Spiesser A. (AB-03) ...... 18 Stiles M.D. (DP-06) ...... 143 Sun A. (AP-01) ...... 35 Skorvanek I. (AR-15) ...... 41 Spiesser A.M. (HB-05) ...... 266 Stiles M.D. (FA-04) ...... 198 Sun A. (AV-13) ...... 50 Skorvanek I. (CG-01) ...... 101 Spinu L. (AH-08) ...... 34 Stiner D.R. (GR-09) ...... 254 Sun A. (DT-10) ...... 152 Skorvanek I. (EF-04) ...... 171 Spinu L. (BU-12) ...... 84 Stobiecki T. (AH-05) ...... 33 Sun A. (EV-15) ...... 193 Skorvanek I. (EF-14) ...... 173 Spivak D. (BP-15) ...... 74 Stobiecki T. (CH-03) ...... 104 Sun A. (EV-16) ...... 194 Skowronski W. (AH-05) ...... 33 Spoth K. (GR-09) ...... 254 Stobiecki T. (CH-04) ...... 105 Sun A. (FR-07) ...... 218 Skowronski W. (CH-03) ...... 104 Sproll M. (BG-06) ...... 68 Stobiecki T. (ES-04) ...... 185 Sun C. (AV-09) ...... 49 Skowronski W. (ES-04) ...... 185 Sreekanth M.K. (GD-13) ...... 239 Stocks G. (DG-13) ...... 139 Sun C. (ED-04) ...... 167 Skumryev V. (AE-10) ...... 26 Srikanth H. (AQ-02) ...... 37 Stocks G. (EU-05) ...... 190 Sun D. (DS-15) ...... 151 Skumryev V. (HH-02) ...... 278 Srikanth H. (AQ-09) ...... 38 Stoehr J. (DU-01) ...... 153 Sun J. (AR-09) ...... 40 Slaughter J. (BA-01) ...... 54 Srikanth H. (AR-12) ...... 41 Stoehr J. (HF-11) ...... 275 Sun J. (BV-05) ...... 86 Slavin A. (CP-03) ...... 107 Srikanth H. (BE-09) ...... 64 Stoehr J. (HH-04) ...... 278 Sun J. (BV-06) ...... 86 Slavin A. (CP-04) ...... 107 Srikanth H. (DS-14) ...... 151 Stohr J. (AA-01) ...... 17 Sun J. (CG-08) ...... 103 Slavin A. (CP-11) ...... 108 Srikanth H. (EE-05) ...... 170 Stohr J. (DU-05) ...... 154 Sun J. (EF-11) ...... 172 Slavin A. (DA-05) ...... 125 Srikanth H. (EF-01) ...... 171 Stöhr J. (FB-04) ...... 199 Sun J. (EQ-04) ...... 181 Slavin A. (FG-07) ...... 209 Srikanth H. (EP-04) ...... 179 Stoian G.M. (EQ-08) ...... 181 Sun J. (EQ-06) ...... 181 Slavin A.N. (GB-04) ...... 233 Srikanth H. (EQ-03) ...... 181 Stojak K. (EW-03) ...... 194 Sun J. (FQ-04) ...... 215 Slavin A.N. (HE-08) ...... 273 Srikanth H. (EW-03) ...... 194 Stokes S. (FT-08) ...... 222 Sun J. (FQ-08) ...... 216 Sluka V. (CU-07) ...... 118 Srikanth H. (FQ-03) ...... 215 Stoleriu L. (BQ-04) ...... 75 Sun J. (GC-06) ...... 236 Smith A. (DH-05) ...... 140 Srikanth H. (GD-07) ...... 238 Stoleriu L. (BU-12) ...... 84 Sun J. (GQ-06) ...... 252 Smith A. (EC-13) ...... 166 Srikanth H. (HD-04) ...... 270 Stoleriu L. (DX-01) ...... 160 Sun J. (GV-04) ...... 261 Smith A.R. (GE-01) ...... 240 Srikanti K. (GV-07) ...... 262 Stoll H. (AC-12) ...... 22 Sun J.F. (AR-12) ...... 41 Smith R. (EF-07) ...... 172 Srinivasan G. (AD-02) ...... 23 Stoll H. (BG-06) ...... 68 Sun J.F. (FQ-03) ...... 215 Smith R. (FT-17) ...... 223 Srinivasan K. (DT-04) ...... 152 Stoll H. (DB-13) ...... 127 Sun J.Z. (AH-04) ...... 33 Smith R. (FT-18) ...... 223 Srinivasan K. (GW-03) ...... 263 Stoll H. (GP-07) ...... 250 Sun J.Z. (BA-02) ...... 54 Smith R.L. (FT-15) ...... 223 Srivastav S.K. (EP-07) ...... 179 Stoller R. (DG-13) ...... 139 Sun K.W. (GF-03) ...... 242 Smith S.A. (BG-15) ...... 70 Srivastava V. (GQ-15) ...... 253 Strache T. (BG-01) ...... 67 Sun L. (AH-10) ...... 34 Smith S.E. (FR-09) ...... 218 Stadler B. (BH-07) ...... 71 Straka L. (GQ-05) ...... 252 Sun L. (BP-03) ...... 73 Smogunov A. (EB-11) ...... 164 Stadler B. (GD-06) ...... 238 Stripe B. (AA-05) ...... 18 Sun L. (DR-09) ...... 148 Sniadecki Z. (DD-11) ...... 132 Stadler B.J. (CF-05) ...... 99 Strydom A.M. (DQ-06) ...... 145 Sun M. (CR-05) ...... 111 Snider C.N. (AB-05) ...... 19 Stadler B.J. (GQ-08) ...... 252 Studer A. (DD-13) ...... 132 Sun M. (ET-01) ...... 187 Snyman J. (DQ-06) ...... 145 Stadler S. (FQ-14) ...... 217 Studer A. (EF-02) ...... 171 Sun M. (GR-11) ...... 255 Soffa W.A. (AF-02) ...... 27 Stadler S. (GQ-10) ...... 253 Studer A.J. (CQ-13) ...... 110 Sun N. (BR-08) ...... 78 Soffner M.E. (FQ-01) ...... 215 Staeck P. (DG-07) ...... 139 Stupic K. (FH-11) ...... 212 Sun N. (CH-05) ...... 105 330 PROGRAM PROGRAM 331

Sun N. (CR-01) ...... 111 Swagten H. (DB-08) ...... 126 Takeuchi I. (AE-11) ...... 27 Taniguchi T. (DC-06) ...... 129 Sun N. (DS-11) ...... 150 Swagten H.J. (BB-06) ...... 56 Takeuchi I. (AF-10) ...... 29 Taniguchi T. (DP-13) ...... 144 Sun N. (DS-13) ...... 151 Swagten H.M. (BG-02) ...... 68 Takeuchi I. (AX-10) ...... 53 Taniguchi T. (EH-13) ...... 178 Sun N. (EG-02) ...... 173 Swagten H.M. (ET-10) ...... 188 Takeuchi I. (CE-02) ...... 97 Taniguchi T. (EU-01) ...... 189 Sun N. (ES-01) ...... 185 Swoboda C. (BP-07) ...... 73 Takeuchi I. (CE-04) ...... 98 Taniguchi T. (GC-11) ...... 237 Sun N. (GG-04) ...... 245 Sykora R. (FD-10) ...... 204 Takeuchi I. (DF-02) ...... 135 Tanikawa K. (BP-12) ...... 74 Sun N.X. (DS-15) ...... 151 Syu B. (HB-07) ...... 266 Takeuchi I. (DF-14) ...... 137 Taniyama T. (ES-02) ...... 185 Sun N.X. (FG-06) ...... 209 Szajek A. (DD-11) ...... 132 Takeuchi I. (DU-11) ...... 155 Tanjore J.V. (HD-06) ...... 270 Sun P. (CR-15) ...... 113 Sze J. (FX-08) ...... 231 Takeuchi Y. (DC-09) ...... 129 Tao B. (GS-02) ...... 256 Sun S.J. (CS-09) ...... 114 Sze J. (GU-05) ...... 260 Takezawa M. (AV-02) ...... 48 Tao L. (GU-03) ...... 259 Sun X. (AE-08) ...... 26 Szunyogh L. (CQ-03) ...... 109 Takezawa M. (FF-03) ...... 206 Tao X. (BP-03) ...... 73 Sun X. (AG-02) ...... 30 Szunyogh L. (HC-05) ...... 268 Takura T. (CR-10) ...... 112 Tarafdar K. (BE-08) ...... 63 Sun X. (AQ-13) ...... 39 Szymanski D. (ER-13) ...... 184 Takura T. (CR-11) ...... 112 Taroni A. (CB-10) ...... 92 Sun X. (BP-16) ...... 74 Takuya Y. (FF-13) ...... 208 Tashiro T. (AG-04) ...... 30 Sun X. (DE-09) ...... 134 - T - Tal N. (FX-09) ...... 231 Taskaev S.V. (BF-12) ...... 67 Sun X. (EQ-09) ...... 181 Talaat A. (CG-09) ...... 103 Tatara G. (FU-07) ...... 224 Sun X. (ES-12) ...... 186 Tabares J. (ER-10) ...... 183 Taleb A. (AG-01) ...... 30 Tatara G. (GA-03) ...... 232 Sun X. (ET-04) ...... 187 Tabat N. (FT-07) ...... 222 Taleb A. (DC-04) ...... 128 Tatay Aguilar S. (DC-11) ...... 129 Sun X. (GH-09) ...... 248 Tacchi S. (AC-02) ...... 20 Talham D.R. (FD-08) ...... 203 Tatay Aguilar S. (HC-10) ...... 269 Sun X. (HH-11) ...... 280 Tacchi S. (AC-05) ...... 21 Tallarida G. (FS-09) ...... 220 Tate K. (GU-09) ...... 260 Sun Y. (BC-02) ...... 58 Tacchi S. (AH-02) ...... 33 Tamaru S. (CB-11) ...... 92 Tate R. (HD-09) ...... 271 Sun Y. (BU-06) ...... 84 Tacchi S. (BU-08) ...... 84 Tamaru S. (CU-05) ...... 118 Tayade R. (AH-06) ...... 33 Sun Y. (CS-07) ...... 114 Tacchi S. (BU-10) ...... 84 Tamaru S. (DC-06) ...... 129 Tchernyshyov O. (AH-03) ...... 33 Sun Y. (CX-12) ...... 124 Tacchi S. (CF-03) ...... 99 Tamaru S. (EH-13) ...... 178 Tchernyshyov O. (GP-10) ...... 250 Sun Y. (DQ-08) ...... 146 Tadaaki O. (BW-02) ...... 87 Tamaru S. (HA-05) ...... 265 Tchoula Tchokonte M.B. (DQ-06) . .145 Sun Y. (DS-03) ...... 149 Taheri P. (FV-01) ...... 226 Tamura K. (CT-02) ...... 115 te Velthuis S. (BD-08) ...... 61 Sun Y. (GC-01) ...... 235 Taheri P. (FV-05) ...... 227 Tamura R. (BF-10) ...... 66 te Velthuis S.G. (BC-02) ...... 58 Sun Y. (GS-05) ...... 256 Taira T. (GB-14) ...... 235 Tan H. (DU-07) ...... 154 Tedesco J.G. (FQ-01) ...... 215 Sun Z. (CT-10) ...... 116 Tajima H. (GC-05) ...... 236 Tan H. (HF-07) ...... 275 Tejada J. (DU-12) ...... 155 Sundararajan J. (CW-02) ...... 121 Takagi H. (AT-09) ...... 45 Tan K. (DW-03) ...... 158 Tejo F. (BQ-13) ...... 76 Supnithi P. (FT-03) ...... 222 Takagi H. (FC-06) ...... 201 Tan M.S. (GR-05) ...... 254 Temple R. (EB-06) ...... 164 Supnithi P. (GW-02) ...... 263 Takahashi A. (AS-10) ...... 43 Tan S. (BP-02) ...... 72 Templeton J. (DF-02) ...... 135 Suresh K.G. (AX-14) ...... 54 Takahashi K. (AR-06) ...... 40 Tan S. (BP-09) ...... 73 Temst K. (CC-09) ...... 94 Suresh K.G. (FQ-07) ...... 216 Takahashi M. (BT-02) ...... 81 Tan S. (DU-09) ...... 154 Teng B.H. (FQ-06) ...... 216 Susaki T. (GH-02) ...... 246 Takahashi M. (BW-02) ...... 87 Tan S. (FU-13) ...... 225 Tenne D.A. (EQ-11) ...... 182 Suter A. (BD-05) ...... 60 Takahashi M. (GU-12) ...... 260 Tanaka K. (CB-13) ...... 92 Teo K. (AU-02) ...... 46 Suto H. (FT-01) ...... 221 Takahashi M. (HD-09) ...... 271 Tanaka M. (BT-17) ...... 83 Teo K. (FX-08) ...... 231 Suto H. (FT-02) ...... 222 Takahashi M. (HF-09) ...... 275 Tanaka M. (ET-08) ...... 188 Teo K. (GU-05) ...... 260 Suzuki D. (AG-14) ...... 32 Takahashi N. (CR-12) ...... 112 Tanaka M. (GT-06) ...... 258 Terakura K. (BF-02) ...... 65 Suzuki D. (AP-02) ...... 35 Takahashi N. (GU-09) ...... 260 Tanaka T. (BU-03) ...... 83 Terrade D. (GD-09) ...... 239 Suzuki D. (CD-05) ...... 95 Takahashi T. (DW-08) ...... 159 Tanaka T. (CT-20) ...... 117 Terrill D. (FT-09) ...... 222 Suzuki K. (BF-06) ...... 66 Takahashi Y. (AP-14) ...... 37 Tanaka T. (FP-03) ...... 213 Terris B. (EE-02) ...... 169 Suzuki K. (CG-02) ...... 102 Takahashi Y. (AR-06) ...... 40 Tanaka T. (FU-02) ...... 224 Terris B.D. (HF-06) ...... 274 Suzuki K. (DG-06) ...... 138 Takahashi Y. (BT-13) ...... 82 Tanamoto T. (AX-06) ...... 53 Terris B.D. (HF-11) ...... 275 Suzuki K. (DW-10) ...... 159 Takahashi Y. (CH-11) ...... 106 Tanamoto T. (HB-04) ...... 265 Teruya S. (BP-04) ...... 73 Suzuki K. (FP-07) ...... 213 Takahashi Y. (DV-06) ...... 156 Tanasa R. (AT-04) ...... 44 Tesch M. (ED-02) ...... 167 Suzuki M. (FF-02) ...... 206 Takahashi Y. (HC-13) ...... 269 Tanasa R. (DX-01) ...... 160 Tetienne J. (BB-13)* ...... 57 Suzuki M. (GG-05) ...... 245 Takamura Y. (AX-05) ...... 53 Tanasa R. (FD-04) ...... 203 Tetienne J. (DU-06) ...... 154 Suzuki R. (ET-04) ...... 187 Takamura Y. (BS-01) ...... 79 Tang C. (DH-14) ...... 142 Tezuka N. (HB-04) ...... 265 Suzuki T. (AV-04) ...... 49 Takamura Y. (BS-08) ...... 80 Tang C. (EF-11) ...... 172 Thabit Abdo Saeed A. (DW-03) . . . .158 Suzuki T. (BS-01) ...... 79 Takamura Y. (FP-16) ...... 214 Tang C. (GS-11) ...... 257 Thakur A. (EX-01) ...... 196 Suzuki T. (FV-11) ...... 227 Takanashi K. (AB-04) ...... 19 Tang H. (FG-07) ...... 209 Thakur A.D. (GS-09) ...... 256 Suzuki T. (HB-02) ...... 265 Takanashi K. (AG-04) ...... 30 Tang S. (AT-02) ...... 44 Thakur J. (FH-04) ...... 211 Suzuki Y. (AD-02) ...... 23 Takanashi K. (BP-01) ...... 72 Tang S. (AT-03) ...... 44 Thakur P. (EX-01) ...... 196 Suzuki Y. (BA-05) ...... 55 Takanashi K. (BP-13) ...... 74 Tang S. (GQ-02) ...... 251 Tham K. (HF-09) ...... 275 Suzuki Y. (BE-01) ...... 62 Takanashi K. (CQ-05) ...... 109 Tang W. (ES-10) ...... 186 Thanh T. (DW-02) ...... 158 Suzuki Y. (BE-10) ...... 64 Takanashi K. (CU-11) ...... 118 Tang W. (FS-06) ...... 220 Thanh T. (FQ-10) ...... 216 Suzuki Y. (BE-12) ...... 64 Takanashi K. (FE-09) ...... 205 Tang W. (FS-07) ...... 220 Thanh T. (GU-11) ...... 260 Suzuki Y. (CP-01) ...... 106 Takano K. (HF-06) ...... 274 Tang W. (FS-10) ...... 220 Thantirige R. (FV-09) ...... 227 Suzuki Y. (CP-05) ...... 107 Takano K. (HF-11) ...... 275 Tang W. (GF-03) ...... 242 Thiaville A. (AU-08) ...... 47 Suzuki Y. (EA-02) ...... 162 Takano Y. (CS-02) ...... 113 Tang X. (AP-16) ...... 37 Thiaville A. (BB-09) ...... 56 Suzuki Y. (EQ-10) ...... 182 Takase K. (CS-02) ...... 113 Tang X. (AV-06) ...... 49 Thiaville A. (BB-13) ...... 57 Suzuki Y. (GB-02) ...... 233 Takechi Y. (EP-15) ...... 180 Tang X. (BP-05) ...... 73 Thiaville A. (BG-14) ...... 70 Suzuki Y. (GU-04) ...... 259 Takeda Y. (AB-10) ...... 19 Tang X. (BR-03) ...... 77 Thiaville A. (DB-05) ...... 126 Suzuki Y. (HA-05) ...... 265 Takeichi Y. (AG-11) ...... 32 Tang X. (BU-07) ...... 84 Thiaville A. (DB-07) ...... 126 Svec jr. P. (CG-01) ...... 101 Takeichi Y. (AV-12) ...... 50 Tang X. (EP-06) ...... 179 Thiaville A. (DP-10) ...... 144 Svec P. (CG-01) ...... 101 Takeichi Y. (BF-09) ...... 66 Tang Y. (AT-02) ...... 44 Thiaville A. (DU-06) ...... 154 Svec P. (EF-04) ...... 171 Takeichi Y. (FF-05) ...... 207 Tang Y. (CQ-06) ...... 109 Thiaville A. (FB-08) ...... 199 Svedlindh P. (CU-09) ...... 118 Takeichi Y. (FF-07) ...... 207 Tang Y. (GQ-02) ...... 251 Thiaville A. (HD-05) ...... 270 Sverdlov V. (EH-04) ...... 176 Takeichi Y. (FF-12) ...... 208 Tang Z. (DP-02) ...... 143 Thiaville A. (HE-07) ...... 273 Sverdlov V. (HB-03) ...... 265 Takemura M. (ET-08) ...... 188 Taniguchi T. (CB-11) ...... 92 Thiele J. (AF-01) ...... 27 Sviridova T.A. (FS-11) ...... 221 Takenaga T. (AS-10) ...... 43 Taniguchi T. (CU-05) ...... 118 Thiess S. (DC-02) ...... 128 332 PROGRAM PROGRAM 333

Thiet D. (GQ-12) ...... 253 Trapanese M. (CV-05) ...... 120 Ueda K. (FU-07) ...... 224 van Dijken S. (ES-04) ...... 185 Thirion C. (BG-10) ...... 69 Trapanese M. (GG-07) ...... 245 Ueda K. (FX-01) ...... 230 van Dijken S. (HA-03) ...... 264 Thiyagarajah N. (DH-01) ...... 140 Treves D. (DT-13) ...... 153 Ueda M. (BP-13) ...... 74 Van Haesendonck C. (FS-11) ...... 221 Thiyagarajah N. (GE-13) ...... 242 Trevino M. (DE-05) ...... 134 Ueda S. (CQ-05) ...... 109 van Lierop J. (AD-09) ...... 24 Thomas A. (EB-04) ...... 163 Trevino M. (HE-02) ...... 272 Ueda T. (FG-05) ...... 209 van Lierop J. (EP-08) ...... 179 Thomas L. (BA-03) ...... 54 Troadec C. (GR-05) ...... 254 Uedono A. (ET-04) ...... 187 van Lierop J. (EP-10) ...... 179 Thompson C.J. (ES-08) ...... 186 Trypniotis T. (AU-11) ...... 47 Uemura T. (AX-01) ...... 52 van Mourik R. (BB-03) ...... 55 Thompson C.J. (ES-09) ...... 186 Tryputen L. (DU-08) ...... 154 Uemura T. (FX-03) ...... 230 Van Waeyenberge B. (AH-07) ...... 33 Thompson C.V. (EU-02) ...... 189 Tryputen L. (FU-11) ...... 225 Uemura T. (GB-14) ...... 235 Van Waeyenberge B. (AU-07) ...... 47 Thompson S.M. (BE-11) ...... 64 Tsai C. (BS-11) ...... 80 Uemura T. (HB-10) ...... 266 Vandermeulen J. (AU-07) ...... 47 Thompson S.M. (HC-12) ...... 269 Tsai C. (EP-09) ...... 179 Ueno S. (AW-11) ...... 51 Vandevelde L. (CR-13) ...... 112 Thomson T. (HC-03) ...... 267 Tsai C.L. (BR-06) ...... 77 Ueno S. (GR-08) ...... 254 Vangelista S. (FS-09) ...... 220 Thönnissen C. (DE-07) ...... 134 Tsai C.L. (HC-04) ...... 268 Ueno T. (AG-11) ...... 32 Vansteenkiste A. (AH-07) ...... 33 Thoroddsen S. (BH-05) ...... 71 Tsai C.S. (BU-16) ...... 85 Ueno T. (BF-09) ...... 66 Vansteenkiste A. (AU-07) ...... 47 Thota S. (CS-13) ...... 115 Tsai C.Y. (EP-03) ...... 178 Ueno T. (FF-05) ...... 207 Vansteenkiste A. (CB-02) ...... 91 Tian D. (DH-07) ...... 141 Tsai C.Y. (HC-04) ...... 268 Uga H. (AE-05) ...... 26 Vansteenkiste A. (EU-03) ...... 190 Tian Y. (DS-03) ...... 149 Tsai H. (FW-06) ...... 229 Uhlir V. (FC-04) ...... 201 Vantomme A. (CC-09) ...... 94 Tian Y. (HE-09) ...... 273 Tsai J. (DT-08) ...... 152 Uhlir V. (GP-03) ...... 249 Varaprasad B. (AP-14) ...... 37 Tiberkevich V. (CP-03) ...... 107 Tsai P. (AR-11) ...... 40 Ulyanov M.N. (BF-12) ...... 67 Varaprasad B. (BT-13) ...... 82 Tiberkevich V. (DA-05) ...... 125 Tschoepe A. (DE-03) ...... 133 Umetsu R.Y. (BS-13) ...... 80 Varaprasad B. (HF-13) ...... 276 Tiberkevich V.S. (GB-04) ...... 233 Tseng C. (CR-14) ...... 112 Umetsu R.Y. (FX-07) ...... 230 Varela J.A. (GS-08) ...... 256 Tiberkevich V.S. (HE-08) ...... 273 Tseng C. (EG-11) ...... 175 Umeyama M. (CP-01) ...... 106 Varela M. (BE-02) ...... 62 Tiberto P. (CF-08) ...... 100 Tseng H. (FA-01) ...... 197 Umezawa J. (AV-05) ...... 49 Varela M. (BE-04) ...... 63 Tiberto P. (GR-03) ...... 254 Tseng Y. (DW-07) ...... 159 Ummelen F.C. (ET-10) ...... 188 Varela M. (DE-01) ...... 133 Tibu M. (AR-15) ...... 41 Tseng Y. (ER-11) ...... 184 Unal A.A. (FC-02) ...... 200 Varela M. (EA-02) ...... 162 Tien S.H. (FS-02) ...... 220 Tsoi M. (CU-02) ...... 117 Unguris J. (CE-04) ...... 98 Varga E. (BB-02) ...... 55 Tietze T. (HE-12) ...... 273 Tsoi M. (EU-10) ...... 191 Unguris J. (GR-13) ...... 255 Varga R. (GQ-07) ...... 252 Timco G. (AQ-10) ...... 38 Tsuchiura H. (CD-01) ...... 95 Urazhdin S. (DA-04) ...... 125 Vargas E. (CW-04) ...... 122 Ting Y. (GS-07) ...... 256 Tsuchiura H. (FF-01) ...... 206 Urazuka Y. (BU-03) ...... 83 Vargas J.M. (AH-08) ...... 34 Ting-ting L. (DS-08) ...... 150 Tsuchiura H. (FF-13) ...... 208 Urazuka Y. (FP-03) ...... 213 Vargas N. (BW-08) ...... 88 Tkach A. (CF-09) ...... 100 Tsuji N. (FF-02) ...... 206 Urazuka Y. (FU-02) ...... 224 Vargas N. (GP-15) ...... 251 Tobola J. (ER-13) ...... 184 Tsujikawa M. (CQ-05) ...... 109 Urbanek M. (GP-03) ...... 249 Vargas N.M. (BQ-08) ...... 76 Toga Y. (AV-04) ...... 49 Tsukada K. (GR-06) ...... 254 Urbano R.R. (AQ-15) ...... 39 Varghese B. (DU-07) ...... 154 Togawa Y. (GD-11) ...... 239 Tsukamoto A. (DU-05) ...... 154 Urbano R.R. (AX-08) ...... 53 Varghese B. (HF-07) ...... 275 Toh Y. (EE-08) ...... 170 Tsukamoto A. (FB-04) ...... 199 Urbano R.R. (CS-03) ...... 113 Vasconcelos M.S. (AP-11) ...... 36 Toh Y. (FE-03) ...... 204 Tsumura K. (DT-14) ...... 153 Urbano R.R. (CS-04) ...... 113 Vasilevskiy I. (BW-10) ...... 88 Tokii M. (DU-14) ...... 155 Tsumura K. (DT-15) ...... 153 Urbano R.R. (CS-05) ...... 114 Vasiliev A.N. (BF-12) ...... 67 Toko K. (AB-10) ...... 19 Tsunashima S. (CT-12) ...... 116 Urcelay-Olabarria I. (AE-10) ...... 26 Vasyuchka V.I. (AC-08) ...... 21 Toko K. (GD-08) ...... 238 Tsunegi S. (CB-11) ...... 92 Useinov A. (GC-07) ...... 236 Vaz C. (CF-09) ...... 100 Tokoro H. (HD-01) ...... 270 Tsunegi S. (CU-05) ...... 118 Usselman R. (EE-03) ...... 169 Vaz C.F. (BG-02) ...... 68 Tokuoka Y. (BT-04) ...... 81 Tsunegi S. (FX-09) ...... 231 Usselman R.J. (EW-15) ...... 196 Vazquez M. (AR-10) ...... 40 Tokutome K. (BS-02) ...... 79 Tsunekawa K. (BS-09) ...... 80 Ustinov A.B. (FS-03) ...... 220 Vázquez M. (DG-03) ...... 138 Tokutome K. (CD-06) ...... 96 Tsunekawa K. (BS-10) ...... 80 Utsumi Y. (AF-13) ...... 29 Vazquez M. (GE-03) ...... 240 Tolley R. (AB-07) ...... 19 Tsunekawa K. (FU-14) ...... 225 Utsumi Y. (FP-07) ...... 213 Vázquez M. (HE-10) ...... 273 Tomasello R. (DH-12) ...... 142 Tsunoda K. (AS-10) ...... 43 Uzvardi L. (HC-05) ...... 268 Vazquez Zubiate L. (GU-08) ...... 260 Tomita H. (CP-05) ...... 107 Tsunoda M. (GU-12) ...... 260 Vazquez-Victorio G. (ED-11) ...... 168 Tomy C.V. (CG-07) ...... 102 Tsuzaki Y. (AS-10) ...... 43 - V - Vedmedenko E. (DE-07) ...... 134 Tomy C.V. (GS-09) ...... 256 Tsymbal E.Y. (EB-11) ...... 164 Veeturi S. (GG-01) ...... 244 Tong B. (AS-11) ...... 43 Tu C. (GS-07) ...... 256 v. Korff Schmising C. (BG-02) ...... 68 Vega V. (BW-08) ...... 88 Tong B. (GS-04) ...... 256 Tu K.T. (FS-02) ...... 220 VafaeeKhanjani M. (AE-12) ...... 27 Vehstedt E. (DP-07) ...... 143 Tong C. (CV-07) ...... 120 Tuan D. (GQ-12) ...... 253 Vaia R. (FD-03) ...... 203 Veiga L. (ED-01) ...... 167 Tong C. (CV-14) ...... 121 Tuan D. (GU-11) ...... 260 Vaishnava P. (FH-04) ...... 211 Veiga L.S. (CQ-07) ...... 109 Tong M. (FQ-09) ...... 216 Tuan N.A. (AQ-16) ...... 39 Valanoor N. (EE-06) ...... 170 Veis M. (AT-06) ...... 44 Tong R. (BA-03) ...... 54 Tuan N.A. (FD-09) ...... 203 Valencia S. (CF-09) ...... 100 Veis M. (AT-07) ...... 45 Topuria T. (GC-06) ...... 236 Tudu B. (FB-08) ...... 199 Valencia S. (FC-02) ...... 200 Veis M. (GQ-05) ...... 252 Torelli P. (CE-01) ...... 97 Tuggle A. (BF-03) ...... 65 Valenzuela R. (ED-11) ...... 168 Velev J. (GC-07) ...... 236 Torii T. (GR-07) ...... 254 Tulapurkar A. (GS-09) ...... 256 Vallejo-Fernandez G. (EP-13) . . . . .180 Velev J.P. (EB-11) ...... 164 Torija M. (BE-04) ...... 63 Tuominen M. (FV-09) ...... 227 Vallejo-Fernandez G. (FH-02) . . . . .210 Vemuri s. (FT-17) ...... 223 Torng T. (BA-03) ...... 54 Turek I. (EB-01) ...... 163 Vallejo-Fernandez G. (FP-09) ...... 213 Vemuri S. (FT-18) ...... 223 Torres L. (BG-08) ...... 69 Turgut E. (EU-08) ...... 190 Valloppilly S. (BF-13) ...... 67 Vemuri S.H. (FT-15) ...... 223 Torriani I.L. (CQ-09) ...... 110 Turgut E. (FB-05) ...... 199 Van de Wiele B. (AH-07) ...... 33 Venkatesan M. (AH-09) ...... 34 Tou A. (DV-07) ...... 157 Turgut Z. (BV-02) ...... 85 Van de Wiele B. (AU-07) ...... 47 Venkatesan M. (GD-10) ...... 239 Toulouse C. (AE-02) ...... 25 Turner J.J. (FB-04) ...... 199 Van de Wiele B. (EU-03) ...... 190 Venky V.T. (ED-04) ...... 167 Tourinho F.A. (DV-10) ...... 157 Txoperena O. (BP-16) ...... 74 van den Brink A. (BB-06) ...... 56 Verba R.V. (GB-04) ...... 233 Toussaint J. (AU-14) ...... 48 Tybell T. (FP-16) ...... 214 van der Heijden I. (EB-07) ...... 164 Verba R.V. (HE-08) ...... 273 Toussaint J. (DB-03) ...... 126 Tyberkevych V. (CP-04) ...... 107 van der Laan G. (AH-11) ...... 34 Verea A. (FP-11) ...... 214 Toussaint J. (FC-05) ...... 201 Tyberkevych V. (FG-07) ...... 209 van der Laan G. (BR-14) ...... 78 Vergnaud C. (AU-10) ...... 47 Trabada D.G. (HE-10) ...... 273 Van Der Laan G. (GP-16) ...... 251 Vergnaud C. (BU-09) ...... 84 Tramtham J. (FE-07) ...... 205 - U - van der Wiel W. (BR-14) ...... 78 Verma S. (EV-11) ...... 193 Tran M. (BC-03) ...... 58 van Dijk C. (DE-04) ...... 133 Vernier N. (AG-12) ...... 32 Tran M. (EH-06) ...... 176 Uchida K. (EC-06) ...... 166 van Dijk N.H. (EF-07) ...... 172 Vernier N. (BB-04) ...... 55 Trapanese M. (BQ-14) ...... 76 Ueda K. (DP-10) ...... 144 van Dijken S. (CH-03) ...... 104 Vernier N. (FU-10) ...... 225 334 PROGRAM PROGRAM 335

Vernier N. (HC-06) ...... 268 Waintal X. (GD-09) ...... 239 Wang K.L. (GD-04) ...... 238 Wang Y. (FH-05) ...... 211 Vernik I.V. (DP-03) ...... 143 Wakamura T. (DP-01) ...... 142 Wang L. (AF-01) ...... 27 Wang Y. (FU-03) ...... 224 Verrucchi P. (FD-03) ...... 203 Walker B. (DS-10) ...... 150 Wang L. (AG-10) ...... 31 Wang Y. (FV-07) ...... 227 Verschuuren M. (GE-06) ...... 241 Wallis T. (CP-11) ...... 108 Wang L. (BE-07) ...... 63 Wang Y. (FX-08) ...... 231 Vetter E. (AF-02) ...... 27 Walowski J. (EU-12) ...... 191 Wang L. (BE-08) ...... 63 Wang Y. (GH-14) ...... 248 Viala B. (BU-15) ...... 85 Walter M. (EB-04) ...... 163 Wang L. (BR-11) ...... 78 Wang Y. (GU-05) ...... 260 Vicent J.L. (HE-06) ...... 272 Walter M. (EH-07) ...... 177 Wang L. (DT-05) ...... 152 Wang Y. (HD-10) ...... 271 Vick A. (FP-09) ...... 213 Wan F. (CU-12) ...... 119 Wang L. (EQ-04) ...... 181 Wang Z. (AR-01) ...... 39 Victora R.H. (BC-08) ...... 59 Wang . (GP-08) ...... 250 Wang M. (BB-05) ...... 56 Wang Z. (AV-09) ...... 49 Victora R.H. (BT-15) ...... 82 Wang A. (CG-13) ...... 103 Wang M. (CF-04) ...... 99 Wang Z. (BC-02) ...... 58 Victora R.H. (CT-11) ...... 116 Wang B. (ET-07) ...... 188 Wang M. (DF-03) ...... 135 Wang Z. (BR-07) ...... 77 Victora R.H. (FE-01) ...... 204 Wang B. (GQ-01) ...... 251 Wang M. (DF-10) ...... 137 Wang Z. (DS-08) ...... 150 Victora R.H. (FE-04) ...... 204 Wang C. (CU-02) ...... 117 Wang M. (FQ-13) ...... 216 Wang Z. (DW-01) ...... 158 Vidal J. (CD-07) ...... 96 Wang C. (DF-12) ...... 137 Wang M. (FV-02) ...... 226 Wang Z. (EQ-04) ...... 181 Vidal-Silva N. (BQ-13) ...... 76 Wang C. (GV-08) ...... 262 Wang M. (GB-05) ...... 233 Wang Z. (GT-04) ...... 258 Vieira A.G. (BU-13) ...... 85 Wang C.R. (FS-02) ...... 220 Wang M.H. (FQ-06) ...... 216 Warburton P. (BB-05) ...... 56 Vila L. (AU-10) ...... 47 Wang D. (AG-10) ...... 31 Wang P. (AP-05) ...... 35 Ward C. (ET-13) ...... 188 Vila L. (AW-05) ...... 51 Wang D. (DS-09) ...... 150 Wang P. (BA-03) ...... 54 Ward M. (AB-01) ...... 18 Vila L. (BB-07) ...... 56 Wang D. (DT-05) ...... 152 Wang Q. (BU-07) ...... 84 Ward R.C. (AD-12) ...... 24 Vila L. (BP-14) ...... 74 Wang F. (CT-05) ...... 115 Wang Q. (FP-15) ...... 214 Ward R.C. (FB-10) ...... 200 Vila L. (BU-09) ...... 84 Wang G. (DR-06) ...... 148 Wang S. (CC-04) ...... 93 Warisarn C. (CT-09) ...... 116 Villegas M. (GS-12) ...... 257 Wang G. (DR-08) ...... 148 Wang S. (DS-03) ...... 149 Warisarn C. (FT-03) ...... 222 Vinai F. (GR-03) ...... 254 Wang G. (FG-12) ...... 210 Wang S. (EE-02) ...... 169 Warisarn C. (GW-02) ...... 263 Vinai G. (AD-08) ...... 24 Wang G. (FS-06) ...... 220 Wang S. (FE-01) ...... 204 Warnicke P. (CU-09) ...... 118 Viola A. (CV-05) ...... 120 Wang G. (FS-10) ...... 220 Wang S. (GS-01) ...... 255 Watanabe K. (GC-11) ...... 237 Viola A. (GG-07) ...... 245 Wang G. (GS-01) ...... 255 Wang S. (GT-03) ...... 258 Watanabe S. (FP-05) ...... 213 Visnovsky S. (CX-04) ...... 123 Wang H. (AR-09) ...... 40 Wang S. (HB-11) ...... 267 Watanabe T. (CS-02) ...... 113 Visnovsky S. (ET-03) ...... 187 Wang H. (AR-12) ...... 41 Wang S.M. (GR-05) ...... 254 Watanabe T. (HD-12) ...... 271 Visnovsky S. (GD-02) ...... 238 Wang H. (BC-13) ...... 59 Wang T. (DU-05) ...... 154 Watanabe Y. (BR-12) ...... 78 Visscher P.B. (CD-03) ...... 95 Wang H. (CG-08) ...... 103 Wang T. (FB-04) ...... 199 Watanabe Y. (DG-06) ...... 138 Vitko V.V. (FS-03) ...... 220 Wang H. (CU-08) ...... 118 Wang T. (HF-11) ...... 275 Watson O. (HH-02) ...... 278 Vittoria C. (CR-16) ...... 113 Wang H. (DT-16) ...... 153 Wang W. (AC-13) ...... 22 Wawro A. (ET-03) ...... 187 Vittoria C. (CX-07) ...... 123 Wang H. (DX-09) ...... 161 Wang W. (BH-01) ...... 70 Wdowik U.D. (FD-10) ...... 204 Vittoria C. (CX-08) ...... 123 Wang H. (EF-09) ...... 172 Wang W. (BX-09) ...... 89 Weber M. (CG-10) ...... 103 Vittoria C. (GB-09) ...... 234 Wang H. (FQ-03) ...... 215 Wang W. (DS-03) ...... 149 Wei C. (DR-04) ...... 147 Vivas L. (AR-10) ...... 40 Wang H. (GC-02) ...... 235 Wang W. (FG-04) ...... 209 Wei D. (AP-08) ...... 36 Vlasin O. (CE-03) ...... 97 Wang J. (AG-15) ...... 32 Wang W. (FR-13) ...... 219 Wei D. (BR-04) ...... 77 Vlasin O. (FC-10) ...... 202 Wang J. (AU-06) ...... 47 Wang W. (GG-08) ...... 245 Wei D. (BR-13) ...... 78 Vobornik I. (ED-03) ...... 167 Wang J. (BC-11) ...... 59 Wang W. (GP-04) ...... 249 Wei D. (DP-01) ...... 142 Vodungbo B. (FB-08) ...... 199 Wang J. (BE-06) ...... 63 Wang X. (AH-03) ...... 33 Wei D. (DT-09) ...... 152 Vogel A. (AC-12) ...... 22 Wang J. (BR-07) ...... 77 Wang X. (BD-09) ...... 61 Wei D. (DX-12) ...... 161 Vogel A. (BG-11) ...... 69 Wang J. (CF-10) ...... 100 Wang X. (CS-08) ...... 114 Wei F. (AP-08) ...... 36 Vogel A. (BP-07) ...... 73 Wang J. (CP-07) ...... 107 Wang X. (DH-06) ...... 140 Wei F. (BR-04) ...... 77 Vogel A. (GE-05) ...... 240 Wang J. (CQ-13) ...... 110 Wang X. (DP-12) ...... 144 Wei F. (DT-09) ...... 152 Vogel J. (AU-08) ...... 47 Wang J. (CR-05) ...... 111 Wang X. (DR-06) ...... 148 Wei J. (BR-07) ...... 77 Vogel J. (AU-14) ...... 48 Wang J. (CT-16) ...... 116 Wang X. (DR-08) ...... 148 Wei J. (BV-11) ...... 86 Vogel J. (DB-05) ...... 126 Wang J. (DD-13) ...... 132 Wang X. (DS-12) ...... 150 Wei J. (DX-08) ...... 161 Vogel J. (GE-12) ...... 242 Wang J. (DH-13) ...... 142 Wang X. (EQ-12) ...... 182 Wei J. (GQ-02) ...... 251 Vogel J. (HC-01) ...... 267 Wang J. (DQ-15) ...... 147 Wang X. (EX-05) ...... 196 Wei J. (GS-13) ...... 257 Vogeler-Wunsch J. (AU-15) ...... 48 Wang J. (DT-16) ...... 153 Wang X. (FG-12) ...... 210 Wei J. (GV-08) ...... 262 Volegov A. (FQ-05) ...... 215 Wang J. (DW-13) ...... 159 Wang X. (GG-04) ...... 245 Wei P. (AB-02) ...... 18 Volkova O.S. (BF-12) ...... 67 Wang J. (ED-10) ...... 168 Wang X. (GP-10) ...... 250 Wei Y. (CU-09) ...... 118 Volmer F. (GC-12) ...... 237 Wang J. (EF-02) ...... 171 Wang X. (GT-04) ...... 258 Wei Z. (AP-15) ...... 37 Volodin A.P. (FS-11) ...... 221 Wang J. (EQ-06) ...... 181 Wang Y. (AG-09) ...... 31 Wei Z. (AS-15) ...... 43 Volvach I. (EH-14) ...... 178 Wang J. (ES-12) ...... 186 Wang Y. (AG-10) ...... 31 Wei Z. (AW-01) ...... 50 Vomir M. (FB-03) ...... 198 Wang J. (EU-15) ...... 191 Wang Y. (AP-08) ...... 36 Wei Z. (BW-07) ...... 88 von den Driesch N. (GC-12) ...... 237 Wang J. (EW-05) ...... 194 Wang Y. (AQ-01) ...... 37 Wei Z. (CW-05) ...... 122 von Molnár S. (BE-07) ...... 63 Wang J. (FP-14) ...... 214 Wang Y. (AS-16) ...... 43 Wei Z. (FP-02) ...... 213 von Molnar S. (EQ-08) ...... 181 Wang J. (FV-06) ...... 227 Wang Y. (BA-03) ...... 54 Wei Z. (FP-10) ...... 214 Voyles P. (GH-05) ...... 247 Wang J. (FV-07) ...... 227 Wang Y. (BR-04) ...... 77 Wei Z. (FW-06) ...... 229 Voyles P.M. (FX-03) ...... 230 Wang J. (FV-10) ...... 227 Wang Y. (BR-11) ...... 78 Weier C. (EA-05) ...... 162 Voznyuk V. (DC-08) ...... 129 Wang J. (GQ-03) ...... 252 Wang Y. (BR-14) ...... 78 Weigand M. (AC-12) ...... 22 Vratislav S. (DE-10) ...... 134 Wang J. (GQ-06) ...... 252 Wang Y. (BR-15) ...... 78 Weigand M. (BG-02) ...... 68 Vukadinovic N. (BU-15) ...... 85 Wang J. (GR-11) ...... 255 Wang Y. (CT-11) ...... 116 Weigand M. (BG-06) ...... 68 Vukadinovic N. (HD-05) ...... 270 Wang J. (GR-14) ...... 255 Wang Y. (CU-10) ...... 118 Weigand M. (CT-15) ...... 116 Vyborny K. (DP-07) ...... 143 Wang J. (GS-03) ...... 256 Wang Y. (DQ-15) ...... 147 Weigand M. (DB-02) ...... 125 Wang J. (GT-13) ...... 259 Wang Y. (DT-09) ...... 152 Weigand M. (DB-13) ...... 127 - W - Wang J. (HG-05) ...... 277 Wang Y. (EF-09) ...... 172 Weigand M. (GP-07) ...... 250 Wang K. (BR-14) ...... 78 Wang Y. (ET-02) ...... 187 Weil R. (AU-13) ...... 48 Wada K. (FP-04) ...... 213 Wang k. (EH-03) ...... 176 Wang Y. (EW-13) ...... 195 Weil R. (DP-10) ...... 144 Wadati H. (CS-01) ...... 113 Wang K.L. (EB-02) ...... 163 Wang Y. (FE-02) ...... 204 Weiler M. (GC-04) ...... 235 Wadley P. (CF-04) ...... 99 Wang K.L. (ES-06) ...... 185 Wang Y. (FG-04) ...... 209 Welbourne A. (CC-10) ...... 94 336 PROGRAM PROGRAM 337

Weller D. (BT-07) ...... 82 Wolf T. (BD-13) ...... 62 Wu R. (GQ-06) ...... 252 Xu M. (FQ-13) ...... 216 Weller D. (HF-05) ...... 274 Woltersdorf G. (BG-06) ...... 68 Wu R. (GV-04) ...... 261 Xu P. (CG-04) ...... 102 Wells A. (BD-09) ...... 61 Woltersdorf G. (GP-07) ...... 250 Wu R. (GV-08) ...... 262 Xu Q. (AE-13) ...... 27 Wen D. (HD-10) ...... 271 Won M. (CX-02) ...... 123 Wu S. (DS-02) ...... 149 Xu X. (AX-09) ...... 53 Wen H. (CD-12) ...... 96 Wong F. (BE-10) ...... 64 Wu S. (EB-08) ...... 164 Xu X. (CT-05) ...... 115 Wen Q. (AT-05) ...... 44 Wong F.J. (AD-02) ...... 23 Wu S. (EV-15) ...... 193 Xu X. (DS-12) ...... 150 Wen Q. (AT-16) ...... 46 Wong F.J. (EQ-10) ...... 182 Wu S. (EV-16) ...... 194 Xu X. (GH-06) ...... 247 Wen Q. (DT-11) ...... 152 Wong H. (DW-03) ...... 158 Wu S. (FR-07) ...... 218 Xu Y. (AX-03) ...... 52 Wen T. (AD-03) ...... 23 Wong P. (BR-14) ...... 78 Wu T. (AP-07) ...... 36 Xu Y. (EC-03) ...... 165 Wen T. (EE-07) ...... 170 Wong S. (HF-07) ...... 275 Wu T. (BS-05) ...... 79 Xu Z. (AW-08) ...... 51 Wen T. (HE-04) ...... 272 Woo B. (CV-06) ...... 120 Wu W. (AE-01) ...... 25 Xu Z. (GS-07) ...... 256 Wen W. (DT-05) ...... 152 Woo S. (AC-07) ...... 21 Wu W. (AE-07) ...... 26 Xu Z. (HE-09) ...... 273 Wen W. (HF-01) ...... 274 Woodard L.E. (EW-11) ...... 195 Wu W. (BE-07) ...... 63 Xue D. (CU-12) ...... 119 Wen X. (CG-06) ...... 102 Woodcock T.G. (FF-10) ...... 207 Wu X. (EP-05) ...... 179 Xue D. (EQ-14) ...... 182 Wen Y. (AS-05) ...... 42 Woods J. (AQ-04) ...... 38 Wu X. (GS-11) ...... 257 Xue D. (ES-15) ...... 186 Wen Y. (AS-06) ...... 42 Woods J. (BC-04) ...... 58 Wu X. (GW-01) ...... 263 Xue D.S. (BR-02) ...... 77 Wen Y. (AS-13) ...... 43 Woods J. (DD-06) ...... 131 Wu Y. (BP-10) ...... 73 Xue Q. (BR-08) ...... 78 Wen Y. (AW-10) ...... 51 Woodward P.M. (BC-13) ...... 59 Wu Y. (DH-11) ...... 141 Xue Q. (DS-11) ...... 150 Wen Y. (DS-09) ...... 150 Worledge D. (BA-02) ...... 54 Wu Z. (BE-06) ...... 63 XueGang C. (ES-05) ...... 185 Wen Z. (AB-09) ...... 19 Worledge D. (CD-11) ...... 96 Wu Z. (FS-07) ...... 220 XueGang C. (FX-02) ...... 230 Wen Z. (GT-06) ...... 258 Worledge D.C. (GC-06) ...... 236 Wu Z. (FS-10) ...... 220 Weng L. (GQ-01) ...... 251 Woytasik M. (HG-03) ...... 276 Wunderlich J. (DP-07) ...... 143 - Y - Weng Y. (BS-11) ...... 80 Wrona J. (ES-04) ...... 185 Wurz M.C. (DG-12) ...... 139 Weng Y. (CQ-06) ...... 109 Wu A. (CS-10) ...... 114 Wysocki A.L. (AE-07) ...... 26 Yadav A. (AB-08) ...... 19 Wereley N.M. (CV-03) ...... 120 Wu B. (BP-10) ...... 73 Wysocki A.L. (FX-04) ...... 230 Yadav R. (HH-03) ...... 278 Wereley N.M. (FW-02) ...... 228 Wu B. (DU-05) ...... 154 Wyss M. (DD-01) ...... 130 Yah S.R. (CS-09) ...... 114 Wereley N.M. (FW-04) ...... 228 Wu B. (FB-04) ...... 199 Yakabe H. (BT-02) ...... 81 Wereley N.M. (FW-11) ...... 229 Wu B. (GE-13) ...... 242 - X - Yakata S. (BG-07) ...... 69 Wereley N.M. (FW-12) ...... 229 Wu B. (HF-11) ...... 275 Yakhou-Harris F. (HC-01) ...... 267 Wernsdorfer W. (FD-04) ...... 203 Wu C.P. (CS-09) ...... 114 Xia W. (AT-02) ...... 44 Yakovlev N. (GE-13) ...... 242 Werwinski M. (DD-11) ...... 132 Wu D. (AH-10) ...... 34 Xia W. (AT-03) ...... 44 Yakushiji K. (BG-04) ...... 68 Wesenberg D. (DP-16) ...... 144 Wu D. (AP-08) ...... 36 Xia W. (BF-11) ...... 67 Yakushiji K. (BS-12) ...... 80 Westover A. (DE-05) ...... 134 Wu D. (BR-04) ...... 77 Xia W. (BV-07) ...... 86 Yakushiji K. (CB-01) ...... 91 Whangbo M.H. (FD-11) ...... 204 Wu D. (GS-01) ...... 255 Xia Y. (FQ-15) ...... 217 Yakushiji K. (CB-11) ...... 92 Wheeler M. (CP-08) ...... 107 Wu D. (HB-11) ...... 267 Xia Y. (GV-08) ...... 262 Yakushiji K. (CP-01) ...... 106 Whig R. (BA-01) ...... 54 Wu G. (CQ-13) ...... 110 Xia Z. (AR-04) ...... 40 Yakushiji K. (CU-05) ...... 118 White J. (DS-01) ...... 149 Wu G. (DS-13) ...... 151 Xiao B. (DS-10) ...... 150 Yakushiji K. (DA-03) ...... 125 White S. (BC-12) ...... 59 Wu G. (GQ-03) ...... 252 Xiao J. (BP-05) ...... 73 Yakushiji K. (DC-03) ...... 128 Whitehead J.P. (GW-03) ...... 263 Wu H. (AP-01) ...... 35 Xiao J. (EP-06) ...... 179 Yakushiji K. (DC-06) ...... 129 Whiteside A. (CC-03) ...... 93 Wu H. (BR-01) ...... 77 Xiao J. (ES-10) ...... 186 Yakushiji K. (EH-12) ...... 177 Wicht S. (HF-05) ...... 274 Wu H. (EG-07) ...... 174 Xiao J. (FS-06) ...... 220 Yakushiji K. (EH-13) ...... 178 Wiedwald U. (BW-09) ...... 88 Wu H. (EP-02) ...... 178 Xiao J.Q. (FA-03) ...... 198 Yakushiji K. (FU-14) ...... 225 Wiekhorst F. (EW-12) ...... 195 Wu H. (FP-08) ...... 213 Xiao J.Q. (HC-07) ...... 268 Yakushiji K. (GU-04) ...... 259 Wiemer C. (FS-09) ...... 220 Wu I. (GS-06) ...... 256 Xiao L. (FG-03) ...... 209 Yakushiji K. (HA-05) ...... 265 Wienholdt S. (FB-06) ...... 199 Wu J. (AX-03) ...... 52 Xiao X. (GV-01) ...... 261 Yamada K. (DP-10) ...... 144 Wiesendanger R. (GB-08) ...... 234 Wu J. (DG-09) ...... 139 Xie C. (AS-16) ...... 43 Yamada K. (DX-02) ...... 160 Wiesendanger R. (GC-13) ...... 237 Wu J. (DU-15) ...... 155 Xie Q. (EP-05) ...... 179 Yamada M. (AC-09) ...... 22 Wieser R. (DE-07) ...... 134 Wu J. (DW-06) ...... 158 Xie T. (DS-15) ...... 151 Yamada M. (DV-08) ...... 157 Wiley J.B. (AT-08) ...... 45 Wu J. (EF-11) ...... 172 Xie Y. (AQ-01) ...... 37 Yamada S. (BP-12) ...... 74 Wilhelm F. (AA-03) ...... 17 Wu J. (EW-06) ...... 195 Xie Y. (DQ-08) ...... 146 Yamada Y. (DG-04) ...... 138 Wilhelm F. (AD-04) ...... 23 Wu J. (FA-03) ...... 198 Xin H. (GF-05) ...... 243 Yamagishi M. (FT-02) ...... 222 Wilhelm F. (DH-15) ...... 142 Wu J. (GU-12) ...... 260 Xin Y. (EQ-08) ...... 181 Yamaguchi M. (DU-02) ...... 153 Williams D. (EC-09) ...... 166 Wu J.C. (BR-06) ...... 77 Xing D. (AR-09) ...... 40 Yamaguchi M. (FT-10) ...... 222 Williams J.F. (ET-04) ...... 187 Wu L. (DH-07) ...... 141 Xing D. (CG-08) ...... 103 Yamaguchi M. (HD-12) ...... 271 Williams R. (GC-02) ...... 235 Wu L. (EQ-14) ...... 182 Xing F. (CV-10) ...... 120 Yamaguchi T. (GC-11) ...... 237 Windbacher T. (EH-04) ...... 176 Wu L. (ET-16) ...... 189 Xing H. (EC-08) ...... 166 Yamakawa K. (GW-08) ...... 264 Windbacher T. (HB-03) ...... 265 Wu M. (AG-10) ...... 31 Xiong J. (GS-02) ...... 256 Yamamoto M. (AX-01) ...... 52 Wingo J. (EW-03) ...... 194 Wu M. (BC-02) ...... 58 Xiong P. (BE-07) ...... 63 Yamamoto M. (FX-03) ...... 230 Wingo J. (HD-04) ...... 270 Wu M. (BU-06) ...... 84 Xiong S. (FE-02) ...... 204 Yamamoto M. (GB-14) ...... 235 Winkler G. (ES-14) ...... 186 Wu M. (CU-13) ...... 119 Xiong S. (FT-14) ...... 223 Yamamoto M. (GH-05) ...... 247 Winklhofer M. (HE-06) ...... 272 Wu M. (CX-12) ...... 124 Xu A. (FV-03) ...... 226 Yamamoto M. (HB-10) ...... 266 Winpenny R.E. (AQ-10) ...... 38 Wu M. (GC-01) ...... 235 Xu B. (BT-11) ...... 82 Yamamoto S. (GT-06) ...... 258 Wintz S. (BG-01) ...... 67 Wu Q. (DR-09) ...... 148 Xu B. (EE-08) ...... 170 Yamamoto T. (BP-01) ...... 72 Wise A. (GD-12) ...... 239 Wu Q. (FG-02) ...... 208 Xu B. (FE-03) ...... 204 Yamanouchi M. (BB-11) ...... 57 Wisniowski P. (CH-03) ...... 104 Wu Q. (FG-03) ...... 209 Xu D. (CR-15) ...... 113 Yamanouchi M. (DC-09) ...... 129 Wisniowski P. (CH-04) ...... 105 Wu Q. (FP-14) ...... 214 Xu F. (DX-08) ...... 161 Yamanouchi M. (DC-10) ...... 129 Witanachchi S. (BE-09) ...... 64 Wu Q. (HG-05) ...... 277 Xu F. (GQ-11) ...... 253 Yamanouchi M. (DH-09) ...... 141 Witanachchi S. (DS-14) ...... 151 Wu R. (BV-05) ...... 86 Xu J. (AW-07) ...... 51 Yamanouchi M. (FU-07) ...... 224 Witt J.D. (EC-05) ...... 165 Wu R. (BV-06) ...... 86 Xu J. (CS-08) ...... 114 Yamasaki K. (BP-12) ...... 74 Wittrock S. (EH-07) ...... 177 Wu R. (BV-11) ...... 86 Xu J. (DH-07) ...... 141 Yamasaki Y. (AF-13) ...... 29 Wolf G. (GC-08) ...... 236 Wu R. (EQ-04) ...... 181 Xu J. (HG-08) ...... 277 Yamashita M. (GW-06) ...... 263 Wolf G.M. (BU-06) ...... 84 Wu R. (EQ-06) ...... 181 Xu L. (FB-07) ...... 199 Yamashita S. (CP-05) ...... 107 338 PROGRAM PROGRAM 339

Yamauchi Y. (AG-02) ...... 30 Yang J. (EV-15) ...... 193 Yesil Z. (BH-12) ...... 72 Youngblood B. (DH-05) ...... 140 Yamauchi Y. (GH-09) ...... 248 Yang J. (EV-16) ...... 194 Yi H. (AQ-02) ...... 37 Youngblood B. (DH-14) ...... 142 Yamaura K. (HH-01) ...... 278 Yang J. (FQ-15) ...... 217 Yi J. (FW-08) ...... 229 Youngblood B. (EC-13) ...... 166 Yamazaki T. (CT-06) ...... 115 Yang J. (FR-07) ...... 218 Yibole X. (FQ-12) ...... 216 Youngblood B. (GD-04) ...... 238 Yamazaki Y. (AS-10) ...... 43 Yang J. (GV-06) ...... 262 Yih P. (DC-12) ...... 130 Youngblood B. (GP-17) ...... 251 Yan A. (AV-06) ...... 49 Yang J. (GV-08) ...... 262 Yin H. (AH-13) ...... 34 Yow H. (DW-03) ...... 158 Yan A. (BV-07) ...... 86 Yang J.K. (GE-13) ...... 242 Yin H. (FT-07) ...... 222 Yu B. (CV-07) ...... 120 Yan A. (EF-05) ...... 171 Yang K. (EE-09) ...... 170 Yin J. (ED-07) ...... 168 Yu D. (FT-09) ...... 222 Yan A. (EV-02) ...... 192 Yang K.S. (CS-09) ...... 114 Yin J. (EU-05) ...... 190 Yu F. (GV-12) ...... 262 Yan A. (EV-05) ...... 192 Yang L. (CB-09) ...... 92 Yin M. (DT-12) ...... 152 Yu G. (CX-01) ...... 123 Yan A. (EV-10) ...... 193 Yang L. (DH-05) ...... 140 Yin W. (AV-06) ...... 49 Yu G. (GT-03) ...... 258 Yan A. (EV-12) ...... 193 Yang L. (EC-13) ...... 166 Yin X. (CH-06) ...... 105 Yu H. (BR-01) ...... 77 Yan A. (GF-08) ...... 243 Yang M. (CW-08) ...... 122 Yin X. (CH-10) ...... 105 Yu H. (CW-01) ...... 121 Yan C. (GF-08) ...... 243 Yang M. (FH-09) ...... 211 Yin X. (DH-11) ...... 141 Yu H. (EG-04) ...... 174 Yan H. (GS-13) ...... 257 Yang M. (FV-06) ...... 227 Yin Y. (BB-06) ...... 56 Yu H. (EG-07) ...... 174 Yan L. (DS-03) ...... 149 Yang Q. (AT-05) ...... 44 Yin Y. (DB-08) ...... 126 Yu H. (EG-11) ...... 175 Yan L. (EF-11) ...... 172 Yang Q. (AT-16) ...... 46 Ying Y. (EV-01) ...... 192 Yu H. (EG-14) ...... 175 Yan L. (GS-05) ...... 256 Yang Q. (BP-05) ...... 73 Yoda H. (BA-05) ...... 55 Yu H. (EQ-02) ...... 180 Yan M. (CH-10) ...... 105 Yang Q. (DS-10) ...... 150 Yoda H. (CP-05) ...... 107 Yu H. (FP-08) ...... 213 Yan M. (DX-11) ...... 161 Yang Q. (DT-11) ...... 152 Yohena R. (HD-07) ...... 271 Yu J.A. (FE-13) ...... 206 Yan S. (EX-05) ...... 196 Yang Q. (EW-13) ...... 195 Yokoo T. (FF-12) ...... 208 Yu L. (BE-07) ...... 63 Yan W. (EW-13) ...... 195 Yang R. (DR-04) ...... 147 Yokota N. (DP-05) ...... 143 Yu L. (DQ-15) ...... 147 Yan Z. (AQ-01) ...... 37 Yang R. (FR-11) ...... 218 Yokota T. (DS-06) ...... 150 Yu L. (GR-14) ...... 255 Yan Z. (DX-05) ...... 160 Yang S. (AG-09) ...... 31 Yonetsu M. (DG-05) ...... 138 Yu N.C. (FX-10) ...... 231 Yan Z. (EQ-02) ...... 180 Yang S. (CU-01) ...... 117 Yonezawa S. (CS-01) ...... 113 Yu R. (BW-04) ...... 87 Yan Z. (EQ-05) ...... 181 Yang S. (DH-06) ...... 140 Yonezawa T. (AT-09) ...... 45 Yu R. (HE-11) ...... 273 Yan Z. (ES-05) ...... 185 Yang T. (DX-09) ...... 161 Yoo G. (DR-15) ...... 149 Yu R.C. (HC-07) ...... 268 Yan Z. (FX-02) ...... 230 Yang W. (FQ-15) ...... 217 Yoo J. (CR-02) ...... 111 Yu S. (DW-02) ...... 158 Yan Z. (GS-03) ...... 256 Yang X. (AS-11) ...... 43 Yoo M. (BG-05) ...... 68 Yu S. (FQ-10) ...... 216 Yanagawa T. (DV-08) ...... 157 Yang X. (AS-16) ...... 43 Yoo M. (EU-16) ...... 191 Yu S. (GU-11) ...... 260 Yanagi K. (DU-02) ...... 153 Yang X. (CR-01) ...... 111 Yoo S. (AU-01) ...... 46 Yu S. (GV-01) ...... 261 Yanagihara H. (AF-03) ...... 28 Yang X. (EB-08) ...... 164 Yoo S. (AU-05) ...... 46 Yu S.C. (AR-12) ...... 41 Yanagihara H. (AF-13) ...... 29 Yang X. (EG-02) ...... 173 Yoo S. (DB-06) ...... 126 Yu S.C. (EF-01) ...... 171 Yanagihara H. (DU-14) ...... 155 Yang X. (ET-01) ...... 187 Yoo S. (FU-09) ...... 225 Yu S.C. (FQ-03) ...... 215 Yanagihara H. (FP-07) ...... 213 Yang X. (FG-06) ...... 209 Yoo S. (FU-15) ...... 226 Yu T. (EU-13) ...... 191 Yanai T. (BR-12) ...... 78 Yang X. (GS-04) ...... 256 Yoo S. (FU-16) ...... 226 Yu W. (DB-12) ...... 127 Yanai T. (BV-13) ...... 87 Yang Y. (BP-10) ...... 73 Yoo T. (GU-14) ...... 261 Yu W. (FT-06) ...... 222 Yanai T. (CG-02) ...... 102 Yang Y. (BV-11) ...... 86 Yoo Y. (ER-08) ...... 183 Yu X. (AT-14) ...... 45 Yanai T. (DG-06) ...... 138 Yang Y. (CS-10) ...... 114 Yoon H. (DW-06) ...... 158 Yu X. (EQ-04) ...... 181 Yanai T. (DV-07) ...... 157 Yang Y. (DR-14) ...... 149 Yoon H. (FV-03) ...... 226 Yu X. (EX-06) ...... 197 Yanai T. (EV-08) ...... 193 Yang Y. (FW-08) ...... 229 Yoon H. (FV-04) ...... 227 Yu Y. (FQ-03) ...... 215 Yanai T. (EV-09) ...... 193 Yang Y. (GV-08) ...... 262 Yoon J. (DB-08) ...... 126 Yu Y. (HF-02) ...... 274 Yang A. (AS-05) ...... 42 Yang Y. (HC-07) ...... 268 Yoon S. (BW-03) ...... 87 Yu Y.Y. (AR-12) ...... 41 Yang A. (AS-13) ...... 43 Yang Y. (HF-07) ...... 275 Yoon S. (DR-10) ...... 148 Yuan B. (CS-07) ...... 114 Yang A. (AW-10) ...... 51 Yang Z. (CS-07) ...... 114 Yoon S. (DW-11) ...... 159 Yuan B. (DQ-08) ...... 146 Yang A. (DS-09) ...... 150 Yang Z. (DQ-08) ...... 146 Yoon S. (EP-01) ...... 178 Yuan F. (AP-01) ...... 35 Yang F. (BC-13) ...... 59 Yano M. (AV-12) ...... 50 Yoon S. (FP-12) ...... 214 Yuan F. (AV-13) ...... 50 Yang F. (CU-08) ...... 118 Yano M. (FF-04) ...... 206 Yoshida C. (AS-10) ...... 43 Yuan L. (CH-10) ...... 105 Yang F. (GC-02) ...... 235 Yano M. (FF-05) ...... 207 Yoshida K. (GH-07) ...... 247 Yuan S. (CS-10) ...... 114 Yang G. (FG-02) ...... 208 Yano M. (FF-07) ...... 207 Yoshida T. (FP-04) ...... 213 Yuasa S. (AB-03) ...... 18 Yang G. (FG-03) ...... 209 Yano M. (FF-12) ...... 208 Yoshida T. (HD-01) ...... 270 Yuasa S. (BA-05) ...... 55 Yang G. (FP-14) ...... 214 Yao K. (BP-10) ...... 73 Yoshida Y. (FP-05) ...... 213 Yuasa S. (BG-04) ...... 68 Yang G. (HG-05) ...... 277 Yao K. (EB-02) ...... 163 Yoshikawa M. (CP-05) ...... 107 Yuasa S. (BS-10) ...... 80 Yang H. (BE-12) ...... 64 Yap Q. (FX-08) ...... 231 Yoshikiyo M. (HD-01) ...... 270 Yuasa S. (BS-12) ...... 80 Yang H. (BT-11) ...... 82 Yap Q. (GU-05) ...... 260 Yoshimi K. (FP-05) ...... 213 Yuasa S. (CB-01) ...... 91 Yang H. (BT-12) ...... 82 Yassine O. (BH-05) ...... 71 Yoshimura S. (FC-08) ...... 201 Yuasa S. (CB-11) ...... 92 Yang H. (BW-04) ...... 87 Yasui A. (FF-02) ...... 206 Yoshimura S. (FS-15) ...... 221 Yuasa S. (CP-01) ...... 106 Yang H. (CT-15) ...... 116 Yasui Y. (AQ-12) ...... 38 Yoshimura T. (AE-05) ...... 26 Yuasa S. (CU-05) ...... 118 Yang H. (DH-11) ...... 141 Yasukawa Y. (EX-04) ...... 196 Yoshimura Y. (FU-07) ...... 224 Yuasa S. (DA-03) ...... 125 Yang H. (DT-12) ...... 152 Yasutomi Y. (AB-10) ...... 19 Yoshio M. (FF-13) ...... 208 Yuasa S. (DC-03) ...... 128 Yang H. (DW-09) ...... 159 Yasutomi Y. (GD-08) ...... 238 Yoshioka T. (FF-01) ...... 206 Yuasa S. (DC-06) ...... 129 Yang H. (FU-04) ...... 224 Yazdani A. (ED-06) ...... 168 You B. (AH-10) ...... 34 Yuasa S. (EH-12) ...... 177 Yang H. (GB-11) ...... 234 Ye K. (BT-11) ...... 82 You B. (BP-03) ...... 73 Yuasa S. (EH-13) ...... 178 Yang H. (GD-09) ...... 239 Ye K. (DT-12) ...... 152 You B. (EG-06) ...... 174 Yuasa S. (FU-14) ...... 225 Yang H. (HE-11) ...... 273 Ye K. (EE-08) ...... 170 You C. (CU-01) ...... 117 Yuasa S. (GU-04) ...... 259 Yang J. (AS-05) ...... 42 Ye K. (FE-03) ...... 204 You C. (DB-08) ...... 126 Yuasa S. (GU-13) ...... 261 Yang J. (AS-06) ...... 42 Ye L. (BS-05) ...... 79 You C. (DB-13) ...... 127 Yuasa S. (HA-05) ...... 265 Yang J. (AS-13) ...... 43 Ye L. (DP-03) ...... 143 You L. (DH-03) ...... 140 Yuasa S. (HB-05) ...... 266 Yang J. (AW-10) ...... 51 Ye L. (FP-11) ...... 214 Young A. (HH-04) ...... 278 Yubuta K. (BD-03) ...... 60 Yang J. (BV-11) ...... 86 Ye L. (HE-05) ...... 272 Young I. (CP-14) ...... 108 Yue G. (FD-04) ...... 203 Yang J. (CR-03) ...... 111 Ye Q. (GV-01) ...... 261 Young I.A. (CD-08) ...... 96 Yue J. (DE-11) ...... 135 Yang J. (DS-09) ...... 150 Yefremenko V. (DU-13) ...... 155 Young I.A. (GT-09) ...... 258 Yue L. (HF-02) ...... 274 340 PROGRAM PROGRAM 341

Yue M. (AV-09) ...... 49 Zhang B. (ED-04) ...... 167 Zhang M. (GS-13) ...... 257 Zhang Y. (DS-11) ...... 150 Yue M. (BF-11) ...... 67 Zhang B. (ES-13) ...... 186 Zhang M. (GV-04) ...... 261 Zhang Y. (ED-05) ...... 168 Yue M. (BV-04) ...... 86 Zhang C. (DH-09) ...... 141 Zhang N. (DS-13) ...... 151 Zhang Y. (EF-05) ...... 171 Yue M. (BV-10) ...... 86 Zhang C. (EQ-09) ...... 181 Zhang P. (AR-12) ...... 41 Zhang Y. (ES-12) ...... 186 Yue M. (CQ-01) ...... 109 Zhang D. (AV-09) ...... 49 Zhang P. (FQ-10) ...... 216 Zhang Y. (EW-05) ...... 194 Yue M. (EV-03) ...... 192 Zhang D. (BP-05) ...... 73 Zhang Q. (AR-11) ...... 40 Zhang Y. (FH-05) ...... 211 Yue M. (EV-07) ...... 193 Zhang D. (BV-04) ...... 86 Zhang Q. (AV-03) ...... 49 Zhang Y. (FR-13) ...... 219 Yue M. (FQ-13) ...... 216 Zhang D. (BV-10) ...... 86 Zhang Q. (CQ-01) ...... 109 Zhang Y. (FT-08) ...... 222 Yue M. (FR-04) ...... 217 Zhang D. (CU-10) ...... 118 Zhang Q. (DW-01) ...... 158 Zhang Y. (FU-08) ...... 225 Yue M. (GV-03) ...... 261 Zhang D. (DE-11) ...... 135 Zhang Q. (ES-13) ...... 186 Zhang Y. (GT-14) ...... 259 Yue M. (GV-05) ...... 262 Zhang D. (EP-06) ...... 179 Zhang Q. (HG-08) ...... 277 Zhang Z. (CR-08) ...... 112 Yue M. (GV-12) ...... 262 Zhang D. (ET-02) ...... 187 Zhang R. (BT-16) ...... 83 Zhang Z. (CS-07) ...... 114 Yuichiro A. (BP-04) ...... 73 Zhang D. (EV-03) ...... 192 Zhang R. (DS-13) ...... 151 Zhang Z. (CW-09) ...... 122 Yuki F. (BP-04) ...... 73 Zhang D. (EV-07) ...... 193 Zhang S. (AT-02) ...... 44 Zhang Z. (DQ-08) ...... 146 Yukiko T.K. (HF-13) ...... 276 Zhang D. (FQ-13) ...... 216 Zhang S. (AT-03) ...... 44 Zhang Z. (DR-13) ...... 149 Yun C. (FG-13) ...... 210 Zhang D. (GV-03) ...... 261 Zhang S. (AU-06) ...... 47 Zhang Z. (DW-01) ...... 158 Yun S. (BU-05) ...... 83 Zhang D. (GV-05) ...... 262 Zhang S. (AX-12) ...... 54 Zhang Z. (DX-09) ...... 161 Yun W. (GQ-14) ...... 253 Zhang F. (AQ-13) ...... 39 Zhang S. (BQ-16) ...... 76 Zhang Z. (EF-09) ...... 172 Yurii K.E. (BW-06) ...... 88 Zhang F. (DF-12) ...... 137 Zhang S. (BV-07) ...... 86 Zhang Z. (EW-05) ...... 194 Yurkin G.Y. (DV-03) ...... 156 Zhang F. (EP-05) ...... 179 Zhang S. (CR-12) ...... 112 Zhang Z. (FQ-09) ...... 216 Yusuf S.M. (DD-07) ...... 131 Zhang F. (HH-11) ...... 280 Zhang S. (CT-16) ...... 116 Zhang Z. (GV-10) ...... 262 Zhang G. (ER-12) ...... 184 Zhang S. (DD-03) ...... 131 Zhao G. (DW-12) ...... 159 - Z - Zhang G. (FT-14) ...... 223 Zhang S. (EB-03) ...... 163 Zhao G. (FV-13) ...... 228 Zhang H. (AP-16) ...... 37 Zhang S. (EC-12) ...... 166 Zhao H. (CP-07) ...... 107 Zabadal J.S. (GG-11) ...... 246 Zhang H. (AT-05) ...... 44 Zhang S. (EX-08) ...... 197 Zhao H. (EU-15) ...... 191 Zach R. (ER-13) ...... 184 Zhang H. (AT-16) ...... 46 Zhang S. (FB-07) ...... 199 Zhao H. (FT-08) ...... 222 Zaher A. (BH-04) ...... 71 Zhang H. (AX-12) ...... 54 Zhang S. (GP-08) ...... 250 Zhao J. (GD-04) ...... 238 Zaher A. (BH-05) ...... 71 Zhang H. (BP-05) ...... 73 Zhang S. (GP-16) ...... 251 Zhao J. (GG-08) ...... 245 Zahradnik M. (AT-07) ...... 45 Zhang H. (BR-03) ...... 77 Zhang S. (GQ-02) ...... 251 Zhao J. (GH-08) ...... 247 Zahradnik M. (GQ-05) ...... 252 Zhang H. (BR-11) ...... 78 Zhang S. (GT-03) ...... 258 Zhao R. (BH-01) ...... 70 Zakotnik M. (EV-03) ...... 192 Zhang H. (BU-07) ...... 84 Zhang T. (AS-11) ...... 43 Zhao S. (BR-01) ...... 77 Zamani A. (AG-08) ...... 31 Zhang H. (CV-12) ...... 120 Zhang T. (BF-08) ...... 66 Zhao S. (EG-07) ...... 174 Zamani A. (AP-04) ...... 35 Zhang H. (CX-01) ...... 123 Zhang T. (HB-09) ...... 266 Zhao S. (FP-08) ...... 213 Zamani A. (CC-08) ...... 94 Zhang H. (CX-10) ...... 124 Zhang W. (AD-03) ...... 23 Zhao T. (EG-13) ...... 175 Zamani A. (HF-12) ...... 275 Zhang H. (DR-06) ...... 148 Zhang W. (AH-10) ...... 34 Zhao W. (FU-08) ...... 225 Zamanpour M. (AV-07) ...... 49 Zhang H. (DT-11) ...... 152 Zhang W. (BF-13) ...... 67 Zhao W. (FU-10) ...... 225 Zamanpour M. (FV-01) ...... 226 Zhang H. (EP-06) ...... 179 Zhang W. (BR-14) ...... 78 Zhao W. (GT-14) ...... 259 Zamanpour M. (FV-05) ...... 227 Zhang H. (EX-06) ...... 197 Zhang W. (CG-14) ...... 104 Zhao X. (AQ-13) ...... 39 Zamiatkina E. (AR-08) ...... 40 Zhang H. (EX-08) ...... 197 Zhang W. (DE-11) ...... 135 Zhao X. (CU-12) ...... 119 Zamiatkina E. (CG-09) ...... 103 Zhang H. (FA-03) ...... 198 Zhang W. (DF-11) ...... 137 Zhao X. (DF-12) ...... 137 Zanini L. (EW-14) ...... 196 Zhang H. (FG-12) ...... 210 Zhang W. (DF-12) ...... 137 Zhao X. (FQ-09) ...... 216 Zapf V. (FD-07) ...... 203 Zhang H. (HD-10) ...... 271 Zhang W. (DF-13) ...... 137 Zhao X. (GV-10) ...... 262 Zarbo L. (DP-07) ...... 143 Zhang J. (AS-05) ...... 42 Zhang W. (FR-15) ...... 219 Zhao X. (HH-11) ...... 280 Zare S. (CR-01) ...... 111 Zhang J. (AS-13) ...... 43 Zhang W. (FW-03) ...... 228 Zhao X.G. (EP-11) ...... 179 Zare S. (EG-02) ...... 173 Zhang J. (AV-09) ...... 49 Zhang W. (HE-01) ...... 272 Zhao Y. (EQ-06) ...... 181 Zavadil R. (ER-03) ...... 183 Zhang J. (AW-10) ...... 51 Zhang W.H. (EX-07) ...... 197 Zhao Y. (FR-15) ...... 219 Zayac B. (DF-14) ...... 137 Zhang J. (BT-11) ...... 82 Zhang W.Y. (FV-12) ...... 228 Zhao Z. (AQ-13) ...... 39 Zayets V. (BS-10) ...... 80 Zhang J. (BV-07) ...... 86 Zhang X. (AP-06) ...... 35 Zhao Z. (BQ-16) ...... 76 Zbarsky V. (EH-07) ...... 177 Zhang J. (BV-10) ...... 86 Zhang X. (BE-07) ...... 63 Zhao Z. (CR-12) ...... 112 Zelechowski J. (AW-15) ...... 52 Zhang J. (CS-10) ...... 114 Zhang X. (CA-03) ...... 90 Zhao Z. (ER-12) ...... 184 Zelezny J. (EB-01) ...... 163 Zhang J. (DS-09) ...... 150 Zhang X. (CE-04) ...... 98 Zhao Z. (GS-03) ...... 256 Zeng H. (CT-05) ...... 115 Zhang J. (DW-01) ...... 158 Zhang X. (CG-05) ...... 102 Zhao Z. (HH-11) ...... 280 Zeng H. (EC-08) ...... 166 Zhang J. (EE-08) ...... 170 Zhang X. (DS-15) ...... 151 Zhen C. (AW-07) ...... 51 Zeng J. (BQ-07) ...... 75 Zhang J. (ET-01) ...... 187 Zhang X. (DW-12) ...... 159 Zheng F. (BR-04) ...... 77 Zeng M. (BW-04) ...... 87 Zhang J. (EV-07) ...... 193 Zhang X. (ES-13) ...... 186 Zheng H. (HH-04) ...... 278 Zeng M. (HE-11) ...... 273 Zhang J. (FE-03) ...... 204 Zhang X. (EV-05) ...... 192 Zheng J. (EV-01) ...... 192 Zeng R. (CF-10) ...... 100 Zhang J. (FQ-13) ...... 216 Zhang X. (EV-10) ...... 193 Zheng L. (GF-05) ...... 243 Zeng T. (DX-07) ...... 160 Zhang J. (FU-11) ...... 225 Zhang X. (FE-02) ...... 204 Zheng P. (CV-07) ...... 120 Zeng Z. (ED-08) ...... 168 Zhang J. (GT-03) ...... 258 Zhang X. (FV-06) ...... 227 Zheng P. (CV-14) ...... 121 Zeng Z. (EH-03) ...... 176 Zhang J. (GT-04) ...... 258 Zhang X. (FV-13) ...... 228 Zheng Q. (AU-06) ...... 47 Zermatten P. (AU-13) ...... 48 Zhang J. (GV-03) ...... 261 Zhang X. (GU-02) ...... 259 Zheng Q. (CT-16) ...... 116 Zhai G.J. (DV-02) ...... 156 Zhang J. (GV-05) ...... 262 Zhang X.L. (ED-08) ...... 168 Zheng Q. (GP-08) ...... 250 Zhai H. (CU-10) ...... 118 Zhang J. (GV-12) ...... 262 Zhang Y. (AR-02) ...... 39 Zheng X. (BV-05) ...... 86 Zhai H. (DE-11) ...... 135 Zhang K. (FG-03) ...... 209 Zhang Y. (AT-11) ...... 45 Zheng X. (BV-06) ...... 86 Zhai H. (ET-02) ...... 187 Zhang L. (AS-12) ...... 43 Zhang Y. (AT-12) ...... 45 Zheng X. (EQ-04) ...... 181 Zhai Y. (BR-14) ...... 78 Zhang L. (CV-10) ...... 120 Zhang Y. (BR-08) ...... 78 Zheng X. (EQ-06) ...... 181 Zhai Y. (CU-10) ...... 118 Zhang L. (EF-07) ...... 172 Zhang Y. (BV-11) ...... 86 Zheng X. (FQ-04) ...... 215 Zhai Y. (DE-11) ...... 135 Zhang L. (FQ-12) ...... 216 Zhang Y. (CG-05) ...... 102 Zheng X. (FQ-08) ...... 216 Zhai Y. (DG-01) ...... 138 Zhang L. (GQ-10) ...... 253 Zhang Y. (CP-07) ...... 107 Zheng X. (GQ-06) ...... 252 Zhai Y. (ET-02) ...... 187 Zhang M. (DX-12) ...... 161 Zhang Y. (CQ-04) ...... 109 Zheng X. (GV-04) ...... 261 Zhai Y. (FH-05) ...... 211 Zhang M. (EF-05) ...... 171 Zhang Y. (CS-07) ...... 114 Zheng Y. (GG-10) ...... 246 Zhang A. (GS-11) ...... 257 Zhang M. (FP-15) ...... 214 Zhang Y. (DQ-08) ...... 146 Zhenhua W. (DR-11) ...... 148 342 PROGRAM

Zhidong Z. (DR-11) ...... 148 Zhu Q. (CT-16) ...... 116 Zhong J. (EW-09) ...... 195 Zhu Q. (GP-08) ...... 250 Zhong P. (AX-12) ...... 54 Zhu S. (AB-10) ...... 19 Zhong Q. (GS-13) ...... 257 Zhu T. (CD-12) ...... 96 Zhong T. (BA-03) ...... 54 Zhu T. (EB-08) ...... 164 Zhong Z. (AX-12) ...... 54 Zhu T. (HC-07) ...... 268 Zhong Z. (BP-05) ...... 73 Zhu X. (CV-11) ...... 120 Zhong Z. (BU-07) ...... 84 Zhu Y. (AS-11) ...... 43 Zhong Z. (EP-06) ...... 179 Zhu Y. (BH-07) ...... 71 Zhou C. (BF-14) ...... 67 Zhu Y. (BU-16) ...... 85 Zhou C.T. (EX-07) ...... 197 Zhu Y. (CS-07) ...... 114 Zhou D. (BW-01) ...... 87 Zhu Y. (EA-03) ...... 162 Zhou D. (EE-04) ...... 169 Zhu Y. (ET-16) ...... 189 Zhou D. (EV-13) ...... 193 Zhu Z. (HG-08) ...... 277 Zhou D. (HE-03) ...... 272 Zhuang L. (FR-13) ...... 219 Zhou G. (GS-11) ...... 257 Zhuang L. (FR-15) ...... 219 Zhou H. (CU-12) ...... 119 Zhuang Y. (HD-12) ...... 271 Zhou L. (GF-02) ...... 242 Zhukov A. (FG-01) ...... 208 Zhou L. (GF-03) ...... 242 Zhukov A.P. (AR-08) ...... 40 Zhou M. (BW-01) ...... 87 Zhukov A.P. (CG-09) ...... 103 Zhou M. (EE-04) ...... 169 Zhukov A.P. (CG-11) ...... 103 Zhou M. (EW-09) ...... 195 Zhukov A.P. (FQ-11) ...... 216 Zhou M. (HE-03) ...... 272 Zhukova V. (AR-08) ...... 40 Zhou P. (EQ-05) ...... 181 Zhukova V. (CG-09) ...... 103 Zhou S. (AE-13) ...... 27 Zhukova V. (CG-11) ...... 103 Zhou S. (DQ-08) ...... 146 Zhukova V. (FG-01) ...... 208 Zhou S. (GH-14) ...... 248 Zhukova V. (FQ-11) ...... 216 Zhou T. (CX-01) ...... 123 Zi Z. (DV-13) ...... 157 Zhou X. (AW-13) ...... 52 Ziemann P. (BW-09) ...... 88 Zhou Y. (CD-02) ...... 95 Zighem F. (AC-02) ...... 20 Zhou Y. (CP-04) ...... 107 Zimanyi G.T. (HE-06) ...... 272 Zhou Y. (DX-07) ...... 160 Zimin A.A. (DV-03) ...... 156 Zhou Y. (GT-04) ...... 258 Zink B. (EC-04) ...... 165 Zhou Y. (HB-11) ...... 267 Zink B.L. (DP-16) ...... 144 Zhou Z. (BR-08) ...... 78 Zins I. (BF-01) ...... 65 Zhou Z. (CR-01) ...... 111 Zirka S. (BQ-11) ...... 76 Zhou Z. (DS-11) ...... 150 Zivieri R. (AC-03) ...... 21 Zhou Z. (DS-15) ...... 151 Zivieri R. (BU-10) ...... 84 Zhou Z. (EG-02) ...... 173 Zivkovic I. (DS-01) ...... 149 Zhou Z. (ES-01) ...... 185 Zohar S. (HB-06) ...... 266 Zhou Z. (GG-04) ...... 245 Zong F. (DT-13) ...... 153 Zhu F. (EB-07) ...... 164 Zou C. (EV-16) ...... 194 Zhu F. (HF-06) ...... 274 Zou C. (FR-07) ...... 218 Zhu F. (HG-04) ...... 276 Zou H. (EE-02) ...... 169 Zhu F.Q. (EE-02) ...... 169 Zou H. (HF-03) ...... 274 Zhu F.Q. (HF-03) ...... 274 Zou L. (AT-14) ...... 45 Zhu J. (BA-03) ...... 54 Zou Y. (GS-01) ...... 255 Zhu J. (BQ-07) ...... 75 Zuo W. (BV-05) ...... 86 Zhu J. (BS-03) ...... 79 Zuo W. (BV-06) ...... 86 Zhu J. (BT-09) ...... 82 Zuo W. (GV-04) ...... 261 Zhu J. (EW-13) ...... 195 Zuo X. (AT-11) ...... 45 Zhu J. (FE-08) ...... 205 Zuo X. (AT-12) ...... 45 Zhu J. (FE-12) ...... 206 Zuo X. (CQ-04) ...... 109 Zhu J. (FU-12) ...... 225 Zuo X. (FS-14) ...... 221 Zhu K. (DH-07) ...... 141 Zusan A. (HE-12) ...... 273 Zhu M. (BW-01) ...... 87 Zvezdin A.K. (AE-02) ...... 25 Zhu M. (EE-04) ...... 169 Zvezdin K. (GP-05) ...... 249 Zhu M. (EV-13) ...... 193 Zvezdin K.A. (DA-03) ...... 125 Zhu M. (GF-05) ...... 243 Zvezdin K.A. (FU-14) ...... 225 Zhu M. (GV-13) ...... 262 Zykov G. (FX-07) ...... 230 Zhu M. (HE-03) ...... 272 Zhu P. (EG-05) ...... 174 Zhu Q. (AU-06) ...... 47 *student nominee World Scientific Online ISSN: 2010-3255 Connecting Great Minds www.worldscientific.com/spin

Free Access to all contents for all registered users

Chief Editor Stuart Parkin (IBM, Almaden, USA)

Managing Editors Ching-Ray Chang (National Taiwan University, Taiwan) Roy Chantrell (The University of York, UK)

Consulting Editors H. Ohno (Tohoku University, Japan) Kang L. Wang (University of California, Los Angeles, USA) Shoucheng Zhang (Stanford University, USA)

Aims and Scope Spin electronics is a rapidly emerging field which is based on taking advantage of the unique properties of the spin of the electron, the nucleus and other fundamental particles, as well as that of the photon. Spin electronics has special importance as conventional electronics reaches its physical limitations. SPIN aims to provide a forum for the presentation of research and review articles of interest to all researchers in the field. The scope of the journal includes (but is not necessarily limited to) the following topics: • Materials • Electrical control of magnetic • Metals properties • Heusler compounds • Organic spintronics • Complex oxides: • Optical phenomena and antiferromagnetic, optoelectronic spin manipulation ferromagnetic • Applications and devices • Dilute magnetic • Novel memories and logic semiconductors devices • Dilute magnetic oxides • Lab-on-a-chip • Semiconductor electronics • Others • Nanodevices • Fundamental and interdisciplinary • Fabrication studies • Characterization • Spin in low dimensional system • Spin injection • Spin in medical sciences • Spin transport • Spin in other fields • Spin transfer torque • Computational materials • Spin torque oscillators discovery www.worldscientific.com