The Contents of the Program Book

▶ PARTNERS AND SPONSORS

The 19th International Conference on Ultrafast Phenomena (UP2014)

Organized by

Japan Intense Light Field Science Society (JILS) Center for Ultrafast Intense Laser Science (CUILS), PARTNERS AND SPONSORS PARTNERS http://www.jils.jp/ the University of Tokyo http://www.cuils.org/

Technical Program supported by In cooperation with

The Optical Society (OSA) European Physical Society (EPS) Innovative Center for http://www.osa.org/ http://www.eps.org/ Coherent Photon Technology (ICCPT)

Supported by

The Chemical Society of Japan (CSJ) http://www.csj.jp/index-e.html The Physical Society of Japan (JPS) http://www.jps.or.jp/english/ The Japan Society of Applied Physics (JSAP) http://www.jsap.or.jp/english/ The Laser Society of Japan (LSJ) http://www.lsj.or.jp/laser/ The Spectroscopical Society of Japan (SPSJ) http://www.bunkou.or.jp/english/

Principal industrial sponsor

Coherent, Inc. http://www.coherent.com/

Also sponsored by

Spectra-Physics Tokyo Instruments, Inc. http://www.spectra-physics.com/ http://www.tokyoinst.co.jp/

XXIV

XXV

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Thorlabs Japan Inc. Japan Thorlabs Corp. Phototechnica Corporation Technology Advanced NTT

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KMLabs, Inc. KMLabs, Corp. Laser Japan K. K. Photonics Hamamatsu Also sponsored by sponsored Also PARTNERS AND SPONSORS AND PARTNERS

▶ SPONSORS AND PARTNERS ▶ CONTENTS

Contents

Partners and Sponsors XXIV

General Information Welcome 1 Conference topics 1 Speaker instructions 1 Postdeadline contributions 1 Poster instructions 2 Proceedings 2 Conference digest 2 Registration information 2 Social program 3

CONTENTS Lunches 3 Warning 3 On-site facilities 3 Sponsor exhibition 3 Exhibitor information 3

Conference committees 4

Timetable 6

Conference site maps and ﬂ oor plans 8

Technical sessions Monday 11 Tuesday 26 Wednesday 41 Thursday 56 Friday 61

Authors' index 64 GENERAL INFORMATION ▶

elcome to Okinawa and to the Chemistry International Conference on Vibrational and conformational dynamics, energy transfer, fem- Ultrafast Phenomena! tochemistry, proton and electron transfer, solvation dynamics, W wave packet dynamics and coherent control of reactions, structural dynamics with X-rays and electrons. This year’s event – the XIX biannual international conference – continues the tradition of bringing together a multi- Biology disciplinary group of researchers sharing a common interest Photosynthesis, vision, heme proteins, photoactive proteins, in science and technology at the highest temporal resolution. photoisomerization in chromoproteins, wavepacket dynamics, Scientists and engineers from all over the world will join us femtobiology, structural dynamics with X-rays and electrons, to take part in this event. medical applications.

The conference will include 315 oral and poster contributions. Electronics & optoelectronics We have scheduled 11 invited, 124 oral and 180 poster presenta- Photoconductivity, generation, propagation and detection of ul- tions over what should be ﬁ ve very full days. The presentations trafast electrical signals, plasmonics, terahertz radiation, electro- are in our opinion exceptional in their scientific quality and optical sampling and detectors. range of topics. Applications A sponsor exhibit featuring leading companies will be held in Real world applications of ultrafast technology, including ultra- conjunction with the meeting. GENERAL INFORMATION fast near-field, nonlinear and confocal microscopes, real-time/ real-space electron microscopy, medical applications, high speed We hope that you will enjoy the unique beauty of Okinawa, the communication, micromachining and more. program, and the opportunity to spend time with colleagues from around the globe.

Sincerely, Speaker instructions

General Chairs Duration of oral presentations are: Kaoru Yamanouchi, University of Tokyo, Japan • 15 minutes (including 3 minutes f or discussion) for Steven Cundiff, JILA, NIST and University of Colorado, USA contributed talks Regina de Vivie-Riedle, Ludwig-Maximilians-University, • 30 minutes (including 5 minutes for discussion) for Germany invited talks Program Committee Chairs Speakers are requested to bring their own computers. Our pro- Makoto Kuwata-Gonokami, University of Tokyo, Japan jectors will be equipped with standard D-SUB 15-pin cables. If Louis DiMauro, Ohio State University, USA your computer is Macintosh, you must bring your own adapter.

Make sure to test your computer and its connection to the pro- Conference topics jector during the coffee break preceding the talk or the afternoon of the day before for those scheduled in the morning. This is mandatory as the schedule is tight and time has to be respected Pulse generation and measurement in order for listeners to move from one lecture hall to the other New sources, new wavelength regimes, frequency conversion during parallel sessions. techniques, amplifiers, attosecond pulse generation, pulse shaping, pulse diagnostics, measurement techniques and Speakers are asked to check-in with the session presider in the frequency standards. conference room ten minutes before the session begins. The lecture halls are equipped with microphones and projectors. Physics Ultrafast nonlinear optical processes, kinetics of non-equilibrium processes, quantum conﬁ nement, coherent transients, nonlinear Postdeadline contributions pulse propagation, novel ultrafast spectroscopic techniques, high intensity physics, attosecond dynamics. As a tradition, the 19th International Conference on Ultrafast Materials science Phenomena will showcase postdeadline presentations. The pur- pose of these contributions is to give conference participants the Highly correlated systems, coherent phonons in solids, carrier opportunity to hear new and signiﬁ cant results in rapidly advanc- dynamics in nanoparticles, carbon-based materials, structural ing areas. Only those papers judged to be truly excellent and dynamics with X-rays and electrons. compelling in their timeliness will be accepted for presentation as an oral contribution. The post deadline papers are scheduled for oral presentation on Thursday July 10 between 16:15 - 18:00 1 ▶ GENERAL INFORMATION

in Room A. Authors will be notiﬁ ed whether their papers have been accepted on Monday July 7 directly at the registration desk. Conference digest Postdeadline papers may be included in the proceedings if the authors can submit the manuscript in a timely manner. An online technical digest including the two-page summaries will be available to the participants.

Poster instructions Registration information 180 posters will be presented during three sessions that will take place on Monday July 7, Tuesday July 8, and Thursday July 9 (all On-site registration fees are as follows: sessions scheduled from 15:45 to 17:15). There will be no oral presentations during this time. Member * Non-member Regular participant 50,000 JPY 60,000 JPY Student 30,000 JPY 40,000 JPY Poster sessions are scheduled to provide an opportunity for Accompanying person 15,000 JPY selected papers to be presented in greater visual details and to facilitate discussions among attendees. To display his/her poster, each author is provided with a 90 cm wide × 210 cm high space * Members of the Japan Intense Light Field Science Society (maximum dimensions). A poster may only be put up on the (JILS), the Optical Society (OSA), the European Physical So- day of the assigned poster session. Each presenter must take ciety (EPS), the Chemical Society of Japan (CSJ), the Physical care to remove his/her poster by no later than 19:00 on the same Society of Japan (JPS), the Japan Society of Applied Physics day. Poster presenters are asked to be at their posters during (JSAP), the Laser Society of Japan (LSJ), and the Spectroscopi- their poster session. Note: Fixing material will be provided. The cal Society of Japan (SPSJ) are eligible to attend UP2014 at a boards will be marked with poster presentation codes. member participant rate. All registered regular and student participants are Proceedings eligible to: • Admission to the technical sessions of the conference. • Online digest including the two page summaries.

GENERAL INFORMATION As at previous conferences, a book of Proceedings of the Ultra- • Hard copy of the proceedings. fast Phenomena XIX will be published. Authors of all accepted • One-year access to the electronic edition of the proceedings. contributions (invited, oral, and poster) are invited to submit a • Sponsor exhibition running from Monday morning to paper for the book of Proceedings. We anticipate this volume to Friday noon time. contain around 300 articles of 3 pages each. The Proceedings • Coffee breaks (Monday July 7 through Friday July 11) as will be published by Springer Verlag. Each conference partici- mentioned in the program. pant will receive a hard copy of the book, as well as a one-year • Lunches (Monday July 7 through Friday July 11). online access to its electronic version. • Welcome reception on Sunday July 6 at 18:00 (the registration desk will be open on this day from 15:00 to 18:00). All papers must follow the format and style set by Springer. Au- • Beach side barbecue party sponsored by Spectra-Physics thor instructions are given on the conference website at: on Tuesday evening, July 8, at 19:00. • Conference banquet dinner on Thursday evening, July 10, http://up2014.org/proceedings.html at 19:00.

The most salient information is the following: An attendee registered as an accompanying person is eligible to the five lunches, coffee service, and the three social events • The paper is limited to no more than 3 pages, including all (welcome reception, beach side barbeque party sponsored by text, ﬁ gures, and references. Spectra-Physics, and conference banquet). They cannot receive • Papers are to be submitted in LaTeX (with PDF) or MS Word the online digest of the conference, or the hard copy or online format by email to [email protected]. Papers version of the proceedings volume. must be submitted no later than 17:00 on July 19, 2014, JST (8:00 on July 19, GMT). A signed Consent to Publish form and high-resolution image files for all figures must accom- Registration hours are as follows: pany each submission. Sunday July 6, 2014 15:00 - 18:00 • No late papers, incorrectly formatted papers, or papers lon- Monday July 7, 2014 8:00 - 12:30 and 13:45 - 17:00 ger than 3 pages will be accepted. Tuesday July 8, 2014 8:00 - 12:30 and 13:45 - 17:00 Wednesday July 9, 2014 8:00 - 12:30 and 13:45 - 17:00 Thursday July 10, 2014 8:00 - 12:30 and 13:45 - 17:00 Friday July 11, 2014 8:30 - 11:00

2 GENERAL INFORMATION ▶

Social program On-site facilities

Sunday July 6, 18:00-19:30 Free wireless Internet access is available at the Okinawa Con- Welcome reception vention Center, to be used at your own risk and discretion. at the Pool Side Garden, Laguna Garden Hotel URL: http://www.laguna-garden.jp/ A message board will be installed near the registration area. Phone: 098 (897) 2121 (To be held in Hagoromo West in case of rain) Sponsor exhibition Tuesday July 8, 19:00-21:00 Beach side barbecue party sponsored by Spectra-Physics Sponsor exhibition booths are situated around the poster session at Ginowan Tropical Beach area. See the list of sponsors on pages XXIV-XXV. The exhibits (To be postponed to Wednesday July 9, 19:00-21:00, will be shown throughout the conference. in case of rain) The exhibition space is located close to the lecture halls and next Thursday July 10, 19:00-22:00 to the poster area, in order to allow the participants easy access Conference banquet dinner to the booths. Coffee breaks are arranged to give the participants in Banquet Hall Hagoromo, Laguna Garden Hotel the opportunity to visit the booths. GENERAL INFORMATION URL: http://www.laguna-garden.jp/ Phone: 098 (897) 2121 Exhibitor information Lunches Exhibitors are able to set up their booths in the morning on Mon- day July 7 from 9:00. All UP2014 attendees are eligible to ﬁ ve lunches (from Monday July 7 to Friday July 11). Lunch will be served in the Exhibition All exhibition equipment and material must be removed by Hall, Okinawa Convention Center. Friday 14:00 at the latest.

Attention

All indoor areas of the Okinawa Convention Center are strictly non- smoking. No food or drink is allowed inside Room A (the Theater).

3 ▶ CONFERENCE COMMITTEES

Conference committees

General Chairs Takayoshi Kobayashi, University of Electro- Kaoru Yamanouchi, University of Tokyo, Japan Communications, Japan Steven Cundiff, JILA, NIST and University of Colorado, USA Jean-Louis Martin, LOB-ENSTA, France Regina de Vivie-Riedle, Ludwig-Maximilians-University, Arnold Migus, École Polytechnique, France Germany R. J. Dwayne Miller, University of Hamburg and University of Toronto, Canada Program Committee Chairs Gérard Mourou, LOA-ENSTA, France Shaul Mukamel, University of California at Irvine, USA Makoto Kuwata-Gonokami, University of Tokyo, Japan Margaret M. Murnane, University of Colorado at Louis DiMauro, Ohio State University, USA Boulder, USA Keith Nelson, Massachusetts Institute of Technology, USA Technical Program Committee Eberhard Riedle, Ludwig Maximilians University, Germany Martin Aeschlimann, University of Kaiserslautern, Germany Norbert F. Scherer, University of Chicago, USA Richard Averitt, Boston University, USA Robert Schoenlein, Lawrence Berkeley National Jens Biegert, Institute of Photonic Sciences, Spain Laboratory, USA Andrea Cavalleri, University of Oxford, UK Charles Shank, Lawrence Berkeley National Laboratory, USA Lin Chen, Northwestern University, USA Antoinette Taylor, Los Alamos National Laboratory, USA Thomas Feurer, University of Bern, Switzerland Andrew M. Weiner, Purdue University, USA Mette Gaarde, Louisiana State University, USA Douwe Wiersma, University of Groningen, Netherlands Nuh Gedik, Massachusetts Institute of Technology, USA Tatsu Yajima, University of Tokyo, Japan Tony Heinz, Columbia University, USA Keitaro Yoshihara, Institute for Molecular Science, Japan Jan Helbing, University of Zurich, Switzerland Ahmed Zewail, California Institute of Technology, USA Kevin Kubarych, University of Michigan, USA Wolfgang Zinth, Ludwig Maximilians University, Germany Alfred Leitenstorfer, University of Konstanz, Germany Ruxin Li, Shangai Institute o f Optics & Fine Mechanics, China Local Organizing Committee Stefan Lochbrunner, University of Rostock, Germany Shinichi Adachi, KEK Jon Marangos, Imperial College of London, UK Masaaki Ashida, Osaka University Jennifer Ogilvie, University of Michigan, USA Satoshi Ashihara, Tokyo University of David Reis, Stanford University and SLAC, USA Agriculture and Technology Charles Schmuttenmaer, Yale University, USA Kazuhiro Ema, Sophia University Greg Scholes, University of Toronto, USA Takao Fuji, IMS Olga Smirnova, Max Born Institute, Germany Muneaki Hase, University of Tsukuba Koichiro Tanaka, Kyoto University, Japan Hirokazu Hasegawa, University of Tokyo Fabrice Vallee, University of Lyon, France Hideki Hashimoto, Osaka City University COMMITTEES David Villeneuve, University of Ottawa, Canada Koji Hatanaka, Academia Sinica Martin Zanni, University of Wisconsin, USA Akiyoshi Hishikawa, Nagoya University Dongping Zhong, Ohio State University, USA Kennosuke Hoshina, Niigata University of Pharmacy and Applied Life Sciences International Advisory Committee Tetsuya Ido, NICT David Auston, University of California at Kunio Ishida, Toshiba Corporate Research & Santa Barbara, USA Development Center Majed Chergui, École Polytechnique Fédérale de Kenichi Ishikawa, University of Tokyo Lausanne, Switzerland Tetsuya Ishikawa, RIKEN Paul Corkum, Steacie Institute for Kunie Ishioka, National Institute for Materials Science Molecular Science, Canada Ryuji Itakura, JAEA Sandro De Silvestri, Politecnico di Milano and ULTRAS Jiro Itatani, University of Tokyo INFM-CNR, Italy Shinichiro Iwai, Tohoku University Kenneth Eisenthal, Columbia University, USA Atsushi Iwasaki, University of Tokyo Thomas Elsaesser, Max Born Institute, Germany Fumihiko Kannari, Keio University Graham Fleming, University of California at Berkeley, USA Reika Kanya, University of Tokyo James G. Fujimoto, Massachusetts Institute of Tsuyoshi Kato, University of Tokyo Technology, USA Masayuki Katsuragawa, University of Charles Harris, University of California at Berkeley, USA Electro-Communications Erich Ippen, Massachusetts Institute of Technology, USA Yosuke Kayanuma, Osaka Prefecture University David Jonas, University of Colorado at Boulder, USA Keisuke Tominaga, Kobe University Wolfgang Kaiser, Technical University of Munich, Germany Masahiro Kitajima, National Defense Academy of Japan Wayne Knox, University of Rochester, USA Takayoshi Kobayashi, University of Electro-Communications Yohei Kobayashi, University of Tokyo 4 CONFERENCE COMMITTEES ▶

Hirohiko Kono, Tohoku University Shik Shin, University of Tokyo Shinya Koshihara, Tokyo Institute of Technology Akira Suda, Tokyo University of Science Yoshiyasu Matsumoto, Kyoto University Tohru Suemoto, University of Tokyo Katsumi Midorikawa, RIKEN Toshinori Suzuki, Kyoto University Kaoru Minoshima, AIST Tahei Tahara, RIKEN Kazuhiko Misawa, Tokyo University of Agriculture and Eiji J. Takahashi, RIKEN Technology Jun Takeda, Yokohama National University Hiroshi Miyasaka, Osaka University Satoshi Takeuchi, RIKEN Yasuhisa Mizutani, Osaka University Koichiro Tanaka, Kyoto University Ryuji Morita, Hokkaido University Katsumi Tanimura, Osaka University Yasuo Nabekawa, RIKEN Tadashi Togashi, RIKEN Katsunori Nakai, University of Tokyo Kenji Torizuka, AIST Kazutaka Nakamura, Tokyo Institute of Technology Ken-ichi Ueda, University of Electro-Communications Hidetoshi Nakano, Toyo University Kiyoshi Ueda, Tohoku University Nobuaki Nakashima, Toyota Physical and Chemical Kazuya Watanabe, Kyoto University Research Institute Shuntaro Watanabe, Tokyo University of Science Katsuya Oguri, NTT Basic Research Laboratories Makina Yabashi, RIKEN Kenji Ohmori, IMS Koichi Yamakawa, JAEA Takashi Ohshima, Hitachi Koichi Yamashita, University of Tokyo Yasuhiro Ohshima, IMS Tomoyuki Yatsuhashi, Osaka City University Ken Onda, Tokyo Institute of Technology Hitoki Yoneda, University of Electro-Communications Akira Sakamoto, Saitama University Masayuki Yoshizawa, Tohoku University Taro Sekikawa, Hokkaido University COMMITTEES

5 ▶ TIMETABLE

Timetable

Sunday, July 6 Monday, July 7 Tuesday, July 8

8:00 Opening Comments, Room A, 8:30 - 8:45 [08.Tue.A] [07.Mon.A] Attosecond Electron Dynamics Attosecond and High Harmonic Generation Room A, 8:30 - 10:15 9:00 Room A, 8:45 - 10:15 Presider: Louis DiMauro Presider: Kaoru Yamanouchi *Thomas Pfeifer, Maurizio Reduzzi, *Katsumi Midorikawa, Ming-Chang Chen, Mauro Nisoli, Shunsuke Adachi, Vincent Juvé, Andrius Baltuska, Chii Dong Lin Dimitrios Charalambidis, Jens Herrmann

10:00 Coffee Break 10:15 - 10:45 Coffee Break 10:15 - 10:45

[07.Mon.B] [07.Mon.C] [08.Tue.B] [08.Tue.C] Electronic and Ultrafast Phenomena Nanotips and Biology Reaction Dynamics in Semiconductors Nanooptics Room B,

Room A, Room B, Room A, 10:45 - 12:30 10:45 - 12:30 10:45 - 12:30 10:45 - 12:30 Presider: 11:00 Presider: Presider: Presider: Erik T.J. Nibbering Kevin Kubarych Daniele Brida Walter Pfeiffer Jennifer Ogilvie Martin Zanni Steven Cundiff Alexander Paarmann Thomas Oliver Heide Ibrahim Kunie Ishioka Kazunori Toma Takeshi Miki Andreas Steinbacher Takeshi Suzuki William Putnam Jeffrey Davis Regina de Vivie-Riedle Kohji Mizoguchi Fumiya Kusa Margherita Maiuri Thomas Wolf Yasushi Shinohara Max Gulde Yutaka Nagasawa Franziska Fennel Itay Gdor *Frank Hegmann Masayuki Yoshizawa Yuki Obara Simon Gelinas 12:00

Lunch Break Lunch Break 12:30 - 14:00 12:30 - 14:00 13:00

[07.Mon.D] [08.Tue.D] 14:00 Correlated Materials Pulse Generation Room A, 14:00 - 15:45 Room A, 14:00 - 15:45 Presider: Ken Onda Presider: Katsumi Midorikawa Roman Mankowsky, Georgi Dakovski, Takao Fuji, Atsushi Yabushita, Rohit Prasankumar, Michael Först, Tim Huber, François Légaré, Eberhard Riedle, 15:00 Paul Beaud, Simon Wall Keisaku Yamane, Jeffrey Moses, Tadas Balciunas

Poster Session I (60 papers) Poster Session II (60 papers) Registration Open 16:00 & Coffee Break & Coffee Break 15:00 - 18:00 15:45 - 17:15 15:45 - 17:15 TIMETABLE

17:00 [07.Mon.E] [08.Tue.E] Condensed Phase Dynamics Singlet Imaging and Charge Transfer Room A, 17:15-19:00 Room A, 17:15 - 19:00 Presider: Shaul Mukamel Presider: Gregory Scholes *Tahei Tahara, Thomas Elsaesser, Carlito Ponseca, Holger Lange, 18:00 Welcome Reception Kevin Kubarych, Toshinori Suzuki, Artem Bakulin, Maxim Pshenichnikov, 18:00 - 19:30 Roland Wilcken, Kaoru Ohta Kiyoshi Miyata, Tiago Buckup, Oleg Kozlov

19:00 Beach side barbecue party sponsored by Spectra-Physics 20:00 19:00 - 21:00

21:00

Invited speakers are marked by an asterisk (*) 6 TIMETABLE ▶

Timetable

Wednesday, July 9 Thursday, July 10 Friday, July 11

8:00 [11.Fri.A] [09.Wed.A] [10.Thu.A] Vibrational Dynamics 2D Spectroscopy Strong THz Field Phenomena in Solids Room A, 8:30 - 10:15 Room A, 8:30 - 10:15 Room A, 8:30 - 10:15 Presider: Tahei Tahara Presider: Steven Cundiff Presider: Koichiro Tanaka Erik T.J. Nibbering, Kevin Kubarych, 9:00 *Giulio Cerullo, Shaul Mukamel, *Ryo Shimano, Yihua Wang, Gregory Scholes, Akshay Rao, Trevor Courtney, Valentyn Prokhorenko, *Matthias Hohenleutner, Jumpei Tayama, Tullio Scopigno, Luuk van Wilderen, Damian Schimpf Vincent Juvé, Alexander Grupp Ken Onda

Coffee Break 10:15 - 10:45 Coffee Break 10:15 - 10:45 Coffee Break 10:15 - 10:45 10:00

[09.Wed.B] [09.Wed.C] [10.Thu.B] Novel Ultrafast [10.Thu.C] Terahertz Electron Diffraction [11.Fri.B] Spectroscopy in Microscopy and Dynamics and Rescattering XFEL and High-order Harmonic Solids Dielectrics Room A, Dynamics Spectroscopy Room A, Room B, 10:45 - 12:30 Room B, 10:45 - 12:30 Room A, 10:45 - 12:30 Presider: 10:45 - 12:30 11:00 10:45 - 12:30 Presider: Presider: Tomoya Okino Frank Hegmann Presider: Reika Kanya Presider: Kazutaka Jesse Clark Barry Bruner Bernhard Mayer Peter Baum Nakamura Takayuki Suzuki Cheng-Tien Chiang Fernando Ardana Yuya Morimoto Patrick Grychtol Ilyas Saytashev Matteo Negro József Fülöp Michael Pullen Marcus Ossiander Walter Pfeiffer *Sergiu Amarie Guillaume Laurent Dmitry Turchinovich Henning Geiseler Antoine Moulet Yusuke Yamanaka Oren Pedatzur Yu Mukai Xinhua Xie Petra Gross Gunter Steinmeyer *Philip Bucksbaum Tatsuya Miyamoto Markus Kitzler Stanislav Kruchinin Sabine Keiber Sim Sangwan Sebastian Heuser Kazuhiko Misawa 12:00 Closing Remarks 12:30 - 12:45

Lunch Break Lunch Break Lunch Hour 12:30 - 14:00 12:30 - 14:00 12:45 - 13:45 13:00

[10.Thu.D] [09.Wed.D] Excited State Dynamics Structural Dynamics 14:00 Room A, 14:00 - 15:45 Room A, 14:00 - 15:45 Presider: Regina de Vivie-Riedle Presider: Eberhard Riedle *Leticia González, Friedrich Temps, Christopher Milne, Hana Cho, Matthew Ross, Sebastian Thallmair, Dominik Bucher, Elena Samoylova, Koji Motomura, Hikaru Kuramochi, Benjamin Fingerhut, Yifeng Jiang 15:00 Henrike Müller-Werkmeister TIMETABLE Coffee Break 15:45 - 16:15 Poster Session III (60 papers) & Coffee Break 16:00 15:45 - 17:15 Postdeadline Papers Room A 16:15 - 18:00 [09.Wed.E] Presider: Makoto Kuwata-Gonokami 17:00 Time-resolved Imaging Room A, 17:15 - 19:00 Presider: Marcos Dantus *Jesse Clark, Daniel Hickstein, Keiki Fukumoto, Yoshio Nishiyama, 18:00 John Papanikolas, Renske van der Veen

19:00

Conference Banquet 20:00 19:00 - 22:00

21:00

Invited speakers are marked by an asterisk (*) 7 ▶ CONFERENCE SITE MAPS AND FLOOR PLANS

Conference site maps and ﬂ oor plans

Beach side barbecue party sponsored by Spectra-Physics

Laguna Garden Hotel Conference Site Okinawa Convention Center Banquet

Committee Meeting Room Room B (Conference Room B5) (Conference Room A1)

Restaurant

Stage

Pergola

Room A (Theater) Exhibition Hall

Main Entrance (Exhibition Hall) Parking Area

Pond

Parking Area

Belfry Parking Area

Beach Side MAPS

Parking Area Parking Area Main Gate Gate

8 CONFERENCE SITE MAPS AND FLOOR PLANS ▶

Room A Oral presentations (Theater)

Room A

Room B Oral presentations (Convention Room A1, Conference Building A)

Room B

Exhibition Hall Posters, Sponsor exhibits and lunches (Exhibition Hall)

To Conference Building B

Posters MAPS

Sponsor Exhibits

Lunches

9 ▶ CONFERENCE SITE MAPS AND FLOOR PLANS

Exhibition Hall Posters, Sponsor exhibits and lunches

Coffee

46 45 16 15

Sponsor exhibits 47 44 17 14 48 43 18 13 49 42 19 12 50 41 20 11

Posters Lunch buffet 51 40 21 10 52 39 22 9 53 38 23 8 54 37 24 7 55 36 25 6

Posters Sponsor exhibits

56 35 26 5 57 34 27 4 Sponsor exhibits 58 33 28 3 59 32 29 2 60 31 30 1 Lunch buffet Sponsor exhibits

Cloak

Registration MAPS

10 TECHNICAL SESSIONS ▶

Monday, July 7 MONDAY

Room A 08:45-10:15 07.Mon.A Attosecond and High Harmonic Generation Presider: Kaoru Yamanouchi (University of Tokyo, Japan)

07.Mon.A.1 08:45 Invited Probing Ultrafast Molecular Dynamics with Intense Attosecond Pulses Katsumi Midorikawa1; 1RIKEN Center for Advanced Photonics, Japan. ABSTRACT Recent results on a new attosecond spectroscopic method called as nonlinear Fourier transform spectroscopy using attosecond pulse train and generation of multi-gigawatt isolated attosecond pulses by the infrared two-color laser ﬁ eld synthesis are reported.

07.Mon.A.2 09:15 Contributed Generation of Bright Isolated Attosecond Soft X-Ray Pulses Driven by Multi-Cycle Mid-Infrared Lasers Ming-Chang Chen1,2, Christopher A. Mancuso1, Carlos Hernandez-Garcia1,3, Franklin Dollar1, Benjamin Galloway1, Dimitar Popmintchev1, Benjamin Langdon4, Amelie Auger4, Pei-Chi Huang2, Barry Walker5, Luis Plaja3, Agnieszka Jaron-Becker1, Andreas Becker1, Margaret Murnane1, Henry Kapteyn1, Tenio Popmintchev1; 1Physics, JILA/University of Colorado at Boulder, USA; 2Institute of Photonics Technologies, National Tsing Hua University, Taiwan; 3Grupo de Investigación en Óptica Extrema, Universidad de Salamanca, Spain; 4Kapteyn-Murnane Labs Inc., USA; 5University of Delaware, USA. ABSTRACT By driving the high harmonic generation process with multi-cycle mid-infrared laser pulses, we demonstrate bright isolated, attosecond soft X-ray pulses for the ﬁ rst time.

07.Mon.A.3 09:30 Contributed Sub-100 fs mid-infrared pulses as driver for a table-top hard x-ray source Jannick Weisshaupt1, Vincent Juvé1, Shi-an Ku1, Marcel Holtz1, Michael Woerner1, Thomas Elsaesser1, Skirmantas Alisauskas2, Audrius Pugzlys2, Andrius Baltuška2; 1Max-Born-Institut Berlin, Germany; 2Photonics Institute, Austria. ABSTRACT Midinfrared powerful 90 fs pulses at a wavelength of λ=3.9µm drive a femtosecond hard x-ray source (Cu~Kα: ħω =8.05 keV). Up to 108 X-ray photons/pulse are generated which is twice as many as with 800 nm drivers of a 100 times higher peak intensity.

07.Mon.A.4 09:45 Contributed Optimization of Quantum Trajectories Driven by Strong-Field Waveforms Stefan Haessler1, Tadas Balciunas1, Guangyu Fan1, Tobias Witting2, Richard Squibb2, Luke Chipperfield3, Amelle Zair2, Giedrius Andriuskaitis2, Audrius Pugzlys2, John W. G. Tisch2, Jonathan P. Marangos2, Andrius Baltuska1; 1Photonics Institute, TU Vienna, Austria; 2Blackett Laboratory, Imperial College, United Kingdom; 3Max Born Institute, Germany. ABSTRACT We combine phase-locked femtosecond pulses with 1.5µm, 1.0µm and 0.5µm wavelength to shape optical cycles and experimentally realize the concept of the “perfect wave for high harmonic generation”. This has far-reaching implications for attosecond spectroscopy.

07.Mon.A.5 10:00 Contributed Optimized waveforms for enhancing high-harmonic yield by synthesizing multi-color laser ﬁ elds Chii Dong Lin1, Cheng Jin1, Gouli Wang2, Fei Wei1, Anh Thu Le1; 1Physics, Kansas State University, USA; 2Physics, Northwest Normal University, China. ABSTRACT High harmonics favoring phase-matching conditions can be enhanced by one to two orders of magnitude if the laser’s waveform is optimized by synthesizing two or three-color ﬁ elds without an increase in the total energy.

11 ▶ TECHNICAL SESSIONS

Room A 10:45-12:30 Room B 10:45-12:30 07.Mon.B Electronic and 07.Mon.C Ultrafast Phenomena in

MONDAY Reaction Dynamics Semiconductors Presider: Kevin Kubarych Presider: Daniele Brida (University of Michigan, (University of Konstanz, United States) Germany)

07.Mon.B.1 10:45 Contributed 07.Mon.C.1 10:45 Contributed [Canceled] Quantum Droplets of Electrons and Holes in GaAs QuantumWells Steven T. Cundiff1,2, Andrew Almand-Hunter1,2, Hebin Li1, 07.Mon.B.2 Contributed 11:00 Martin Mootz3, Mackillo Kira3, Stephan W. Koch3; 1JILA, Tabletop Imaging of structural Evolutions in NIST and University of Colorado, USA; 2Physics Department, chemical Reactions University of Colorado, USA; 3Department of Physics, Philipps- Heide Ibrahim1, Benji Wales2, Samuel Beaulieu1, Bruno E. University Marburg, Germany. Shmidt1, Nicolas Thiré1, Éric Bisson1, Christoph Hebeisen3,4, ABSTRACT We present evidence for electron-hole quantum droplets in Vincent Wanie1, Mathieu Giguére1, Jean-Claude Kieffer1, GaAs quantum wells using transient-absorption spectroscopy. Quantum Joseph Sanderson2, Michael Schuurman3, François Légaré1; droplets have a correlation function characteristic of a liquid, but have 1INRS EMT, Canada; 2Physics and Astronomy, University of quantized binding energy, unlike macroscopic droplets. Waterloo, Canada; 3NRC, Canada; 4Physics, Universitiy of Ottawa, Canada. 07.Mon.C.2 11:00 Contributed ABSTRACT The first high-resolution molecular movie of proton migration in the acetylene cation is obtained using a tabletop multiphoton Carrier-phonon Dynamics at Buried Interfaces pump-probe approach - an alternative to demanding free-electron-lasers of GaP/Si(001) and other VUV light sources when ionizing from the HOMO-1. Kunie Ishioka1, Kristina Brixius2, Andreas Beyer2, Wolfgang Stolz2, Kerstin Volz2, Ulrich Höfer2, Hrvoje Petek3; 1National Institute for Materials Science, Japan; 2Philipps-University, 07.Mon.B.3 11:15 Contributed Germany; 3University of Pittsburgh, USA. The Ultrafast Wolff Rearrangement in ABSTRACT Phonon-plasma coupling dynamics of lattice-matched the Gas Phase GaP/Si(001) interface is investigated by photo-doping with femtosecond Andreas Steinbacher1, Sebastian Roeding1, Tobias NUV pulses. Anti-phase domains arising from the interfaces are found Brixner1, Patrick Nuernberger1,2; 1Institut für Physikalische to induce steep band bending within the nanometer-thick GaP ﬁ lm. und Theoretische Chemie, Universität Würzburg, Germany; 2Physikalische Chemie II, Ruhr-Universität Bochum, Germany. 07.Mon.C.3 11:15 Contributed ABSTRACT The sub-picosecond Wolff rearrangement of gas-phase 5-diazo Meldrum’s acid is disclosed with femtosecond ion spectroscopy. Rabi Oscillations in an InAs Quantum Dot Distinct differences are found for 267 nm and 200 nm excitation, the latter Ensemble Observed in leading to even two ultrafast rearrangement reactions. pre-pulse 2D Coherent Spectroscopy Takeshi Suzuki1, Rohan Singh1,2, Ilya Akimov3,4, Manfred Bayer3, Dirk Reuter5, Andreas Wieck5, Steven T. Cundiff1,2; 07.Mon.B.4 11:30 Contributed 1JILA, University of Colorado and National Institute of Sub-Femtosecond Steering of Standards and Technology, USA; 2Physics, University of Carbonhydrogen Bonds Colorado, USA; 3Experimentelle Physik 2, Technische 4 Robert Siemering1, Matthias Kübel1, Boris Bergues2, Universität Dortmund, Germany; A. F. Ioffe Physical-Technical 3,4 1,2 1 Institute, Russian Academy of Sciences, Russian Federation; Ali Alnaser , Matthias Kling , Regina de Vivie-Riedle ; 5 1Ludwig-Maximillians-Universität München, Germany; Angewandte Festkörperphysik, Ruhr-Universtaet Bochum, 2Max-Planck-Institut für Quantenoptik, Germany; 3American Germany. University of Sharjah, United Arab Emirates; 4King-Saud ABSTRACT Pre-pulse 2D coherent spectroscopy is used to observe University, Saudi Arabia. Rabi oscillations in an InAs quantum dot ensemble. The 2D spectra can monitor the coherent evolution in an ensemble system despite ABSTRACT During sub-femtosecond double ionization of acetylene inhomogeneous broadening. vibrational wavepackets are formed which contain the directional information on the targetted hydrocarbon bond. The mechanism for preferential deprotonation of individual bonds is demonstrated by 07.Mon.C.4 11:30 Contributed quantum dynamical simulations. Dynamical Coupling of Rabi Oscillation to Coherent Phonon in 07.Mon.B.5 11:45 Contributed Semiconductor Microcavities Time-resolved photoelectron spectroscopy Kohji Mizoguchi1, Shngo Yoshino1, Goro Oohata1; 1Physical 12 TECHNICAL SESSIONS ▶

and ab initio multiple spawning studies of Science, Osaka Prefecture University, Japan. hexamethylcyclopentadiene ABSTRACT We report on the dynamical coupling between Rabi MONDAY Thomas Wolf1,2, Thomas S. Kuhlman3, Oliver Schalk4,5, Todd oscillation and coherent phonon in CuCl semiconductor microcavities, which induces the time-dependent frequency-shift of the coherent J. Martínez2,6, Klaus B. Møller3, Albert Stolow5, Andreas- phonon mode driven by Rabi oscillation. Neil Unterreiner1; 1Institut für Physikalische Chemie, Karlsruhe Institute of Technology (KIT), Germany; 2Stanford PULSE 3 Institute, Stanford University, USA; Department of Chemistry, 07.Mon.C.5 11:45 Contributed Technical University of Denmark, Denmark; 4Stockholm University, Sweden; 5National Research Council, Canada; Ab-initio theoretical approach to 6Department of Chemistry, Stanford University, USA. coherent phonon generation in solids 1,2 1 1,3 ABSTRACT Time-resolved photoelectron spectroscopy and ab initio Yasushi Shinohara , Shunsuke A. Sato , Kazuhiro Yabana , multiple spawning were applied to the ultrafast non-adiabatic dynamics Tomohito Otobe4, Jun-Ichi Iwata5, George F. Bertsch6; of hexamethylcyclopentadiene. The high level of agreement between 1Graduate School of Pure and Applied Sciences, University of experiment and theory associates wavepacket motion with a distinct Tsukuba, Japan; 2Max-Planck Institut für Mikrostrukturphysik, degree of freedom. Germany; 3Center for Computational Sciences, University of Tsukuba, Japan; 4Kansai Photon Sciences Institute, Japan Atomic Energy Agency, Japan; 5Department of Applied Physics, 07.Mon.B.6 12:00 Contributed University of Tokyo, Japan; 6Department of Physics, University of Washington, USA. S2 to S1 Relaxation Dynamics in Perylene Bisimide Dye Aggregates and Monomers ABSTRACT We investigate mechanisms of coherent phonon generation in time-dependent density-functional theory. It provides Steffen Wolter1, Franziska Fennel1, Marco Schröter1, intuitive understanding of the generation mechanism as well as its Jan Schulze1, Frank Würthner2, Oliver Kühn1, Stefan change depending on electric ﬁ eld frequency. Lochbrunner1; 1Institut für Physik, Universität Rostock, Germany; 2Institut für Organische Chemie and Center for Nanosystems Chemistry, Universität Würzburg, Germany. 07.Mon.C.6 12:00 Contributed ABSTRACT The ultrafast relaxation from the S to the S state 2 1 Novel Spectral Decay Dynamics of in perylene bisimides is investigated by femtosecond absorption spectroscopy. The relaxation takes place on a timescale of 150 fs and Hot Excitons in PbSe Nano-Crystals 1 1 2 1 accelerates slightly upon aggregation. Itay Gdor , Chunfan Yang , Diana Yanover , Hanan Sachs , Efrat Lifshitz2, Sanford Ruhman1; 1Institute of Chemistry, The Hebrew University, Israel; 2Department of Chemistry and Solid 07.Mon.B.7 12:15 Contributed State Institute, Technion, Israel. Femtosecond time-resolved X-ray absorption ABSTRACT Ultrafast exciton cooling in highly mono-disperse PbSe spectroscopy by a multichannel spectral nanocrystals (NC) is followed with tunable pump - Hyperspectral detection using a hard X-ray free electron laser near-IR probe spectroscopy. Unexpected kinetic and spectral correlations are revealed arguing against the standard models for 1 2 3 Yuki Obara , Tetsuo Katayama , Yoshihiro Ogi , Takayuki excited NC absorption. Suzuki1,4, Naoya Kurahashi5, Shutaro Karashima5, Yuhei Chiba1, Yusuke Isokawa1, Tadashi Togashi6, Yuichi Inubushi6, Makina Yabashi6, Toshinori Suzuki3,5, Kazuhiko Misawa1,4; 07.Mon.C.7 12:15 Contributed 1Department of Applied Physics, Tokyo University of Agriculture 2 Ultrafast Long-Range Charge Separation in and Technology, Japan; Japan Synchrotron Radiation Research Organic Semiconductor Photovoltaic Diodes Institute, Japan; 3RIKEN Center for Advanced Photonics, 1 1 1 Japan; 4Interdisciplinary Research Unit in Photon-nano Science, Simon Gelinas , Akshay Rao , Abhishek Kumar , Samuel L. 1 1 1 2 Tokyo University of Agriculture and Technology, Japan; 5Kyoto Smith , Alex Chin , Jenny Clark , Tom S. van der Poll , Guillermo 2 1 1 University, Japan; 6RIKEN SPring-8 Center, Japan. C. Bazan , Richard Friend ; Cavendish laboratory, University of 2 ABSTRACT We have performed the first time-resolved X-ray Cambridge, United Kingdom; Center for Polymers and Organic absorption spectroscopy using the SACLA with a dual-beam dispersive Solids, University of California, Santa Barbara, USA. detection method. The photoexcited iron complex exhibits a red-shifted ABSTRACT By tracking the modulation of the optical absorption iron K-edge with a rise time constant of 260 fs. due to the electric ﬁ eld generated between the charges, we are able to observe the ultrafast electron-hole separation process in organic photovoltaic materials.

13 ▶ TECHNICAL SESSIONS

Room A 14:00-15:45 07.Mon.D Correlated Materials Presider: Ken Onda (Tokyo Institute of Technology, Japan) MONDAY

07.Mon.D.1 14:00 Contributed Transient atomic structure of vibrationally excited YBCO with enhanced superconducting coherence above Tc Roman Mankowsky1, Alaska Subedi2, Michael Foerst1, Simon Mariager3, Matthieu Chollet4, Henrik Lemke4, Joe Robinson4, James Glownia4, Michael Minitti4, Alex Frano5, Michael Fechner6, Nicola Spaldin6, Toshinao Loew5, Mathieu Le Tacon5, Bernhard Keimer5, Antoine George2, Andrea Cavalleri1,7; 1Condensed Matter Dynamics, Max Planck Institute for the Structure and Dynamics of Matter, Germany; 2Strongly Correlated Quantum Materials Group, Ecole Polytechnique, France; 3FEMTO Group, Paul Scherrer Institut, Switzerland; 4Linac Coherent Light Source, SLAC, USA; 5Solid State Spectroscopy, Max Planck Institute for Solid State Research, Germany; 6Materials Theory, Eidgenooessische Technische Hochschule Zuerich, Switzerland; 7Clarendon Laboratory, Oxford University, United Kingdom.

ABSTRACT Nonlinear lattice excitation in YBa2Cu3O6.5 has been shown recently to transiently induce signatures of superconducting coherence up to room temperature. Here, we present ultrafast x-ray diffraction measurements used to determine the corresponding atomic structure.

07.Mon.D.2 14:15 Contributed Selective THz excitation of collective modes in underdoped YBCO Georgi L. Dakovski1, Wei-Sheng Lee2, Joshua J. Turner1, Matthias C. Hoffmann1; 1LCLS, SLAC National Accelerator Laboratory, USA; 2SIMES, SLAC National Accelerator Laboratory, USA. ABSTRACT We use intense broadband THz pulses to excite underdoped YBCO exhibiting competing superconducting and charge density wave ground states. We observe pronounced coherent oscillations at 1.85 and 2.65THz, attributed to renormalized low-energy phonon modes.

07.Mon.D.3 14:30 Contributed Ultrafast optical manipulation of interfacial magnetoelectric coupling Yu-Miin Sheu1, Stuart Trugman1, Li Yan1, Quanxi Jia1, Antoinette J. Taylor1, Rohit P. Prasankumar1; 1Center for Integrated Nanotechnologies, Los Alamos National Laboratory, USA. ABSTRACT We demonstrate a new paradigm for all-optical detection and control of interfacial magnetoelectric coupling on ultrafast timescales, achieved by using time-resolved second harmonic generation (SHG) in a ferroelectric/ferromagnet oxide heterostructure.

07.Mon.D.4 14:45 Contributed Heterogeneous Magnetic Order Melting Triggered by Ultrafast Lattice Control at

the LaAlO3/NdNiO3 Interface Michael Först1, Andrea D. Caviglia2, Raoul Scherwitzl3, Pavlo Zubko3, Hubertus Bromberger1, Roman Mankowsky1, Stuart B. Wilkins4, Yi-De Chuang5, Wei-Sheng Lee6, William F. Schlotter7, Joshua J. Turner7, Georgi L. Dakovski7, Michael Minitti7, Joe Robinson7, Jean-Marc Triscone3, Sarnjeet S. Dhesi8, Andrea Cavalleri1,9; 1Max Planck Institute for the Structure and Dynamics of Matter, Germany; 2Kavli Institute of Nanoscience, Delft University of Technology, Netherlands; 3Département de Physique de la Matière Condensée, University of Geneva, Switzerland; 4Condensed Matter Physics and Materials Science Department, Brookhaven National Laboratory, USA; 5Advanced Light Source, Lawrence Berkeley Laboratory, USA; 6SIMES, Stanford Linear Accelerator Center, USA; 7Linac Coherent Light Source, Stanford Linear Accelerator Center, USA; 8Diamond Light Source, United Kingdom; 9Department of Physics, University of Oxford, United Kingdom. ABSTRACT We use femtosecond Resonant Soft X-ray Diffraction to observe heterogeneous melting of antiferromagnetic order in an epitaxially

grown NdNiO3 ﬁ lm. Cross-interface coupling launches a propagating phase front following direct lattice excitation of the LaAlO3 substrate.

07.Mon.D.5 15:00 Contributed Coherent dynamics of structural symmetry during the ultrafast melting of a charge density wave Tim Huber1, Simon Mariager2, Andres Ferrer1,2, Hanjo Schäfer3, Jeremy A. Johnson2, Sebastian Gruebel2, Andrea Luebcke2,5, Andrin Caviezel2, Lucas Huber1, Teresa Kubacka1, Christian Dornes1, Claire Laulhe6, Sylvain Ravy6, Gerhard Ingold2, Paul Beaud2, Jure Demsar3,4, Steven L. Johnson1; 1ETH Zurich, Switzerland; 2Swiss Light Source, Paul Scherrer Institut, Switzerland; 3Physics Department, Universitaet Konstanz, Germany; 4Ilmenau University of Technology, Institute of Physics, Germany; 5Laboratoire de Spectroscopie Ultrarapide, EPF Lausanne, Switzerland; 6Synchrotron SOLEIL, France. ABSTRACT We use time-resolved hard x-ray diffraction to directly follow the dynamics of structural symmetry change during the ultrafast melting of a charge density wave. We observe a transient recovery of the periodic lattice distortion on a sub-picosecond timescale. 14 TECHNICAL SESSIONS ▶

07.Mon.D.6 15:15 Contributed A detailed view of an ultrafast phase transition using femtosecond resonant x-ray diffraction MONDAY Paul Beaud1,2, Andrin Caviezel1, Simon Mariager1, Laurenz Rettig1, Gerhard Ingold2, Christian Dornes3, Shi-Wen Huang1, Jeremy A. Johnson1, Milan Radovic1,2, Tim Huber3, Teresa Kubacka3, Andres Ferrer1,3, Henrik Lemke4, Matthieu Chollet4, Diling Zhu4, James Glownia4, Marcin Sikorski4, Aymeric Robert4, Hiroki Wadati5,6, Masao Nakamura6, Masashi Kawasaki5,6, Yoshinori Tokura5,6, Steven L. Johnson3, Urs Staub1; 1Swiss Light Source, Paul Scherrer Institut, Switzerland; 2SwissFEL, Paul Scherrer Institut, Switzerland; 3Institute for Quantum Electronics, ETH Zürich, Switzerland; 4LCLS, SLAC National Accelerator Laboratory, USA; 5Department of Applied Physics and Quantum-Phase Electronics Center, University of Tokyo, Japan; 6Center for Emergent Matter Science (CEMS), RIKEN, Japan. ABSTRACT We apply time-resolved resonant x-ray diffraction near the Mn K-edge to directly measure the structural and electronic long-range order changes during ultrafast melting of the charge and orbitally ordered phase in a perovskite manganite.

07.Mon.D.7 15:30 Contributed Competition Between Thermal and Non-Thermal Processes During Femtosecond Switching of Phase Change Materials Simon Wall1, Lutz Waldecker2, Timothy A. Miller1, Ralph Ernstorfer2, Valerio Pruneri1, Miquel Rude1, Robert Simpson3; 1ICFO- Institut de Ciencies Fotoniques, Spain; 2Physical Chemistry, Fritz Haber Institute of the Max Planck Society, Germany; 3Singapore University of Technology and Design, Singapore.

ABSTRACT We use ultrafast optics and electron diffraction to measure irreversible amorphization of crystalline Ge2Sb2Te 5 phase change fi lms. We fi nd that light directly modifi es the local bonding environment leading to a hardening of bonds.

Exhibition Hall 15:45-17:15

07.Mon.P1 Poster Session I

07.Mon.P1.1 Discriminating Racemic from Achiral Solutions with Femtosecond Accumulative Spectroscopy Andreas Steinbacher1, Patrick Nuernberger1, Tobias Brixner1; 1Institut für Physikalische und Theoretische Chemie, Universität Würzburg, Germany. ABSTRACT We follow asymmetric photodissociation reactions of chiral substances with a sensitive polarimeter specifically designed for applications with femtosecond pulses. The accumulative detection scheme allows the discrimination of racemic and achiral solutions with high sensitivity.

07.Mon.P1.2 Filament-driven Lasing Action for Combustion Diagnosis Huailiang Xu1,3, Wei Chu1,2, Helong Li1, Jielei Ni2, Bin Zeng2, Jinping Yao2, Haisu Zhang2, Guihua Li2, Chengrui Jing2, Hongqiang Xie2, Kaoru Yamanouchi3, Ya Cheng2; 1Jilin University, China; 2SIOM, China; 3The University of Tokyo, Japan. ABSTRACT We report on the lasing action for the combustion intermediate of CN in an ethanol/air fl ame by femtosecond laser excitation. It is confi rmed that the lasing action results from amplifi ed spontaneous emission with the population inversion achieved in the femtosecond-laser- induced plasma fi lament.

07.Mon.P1.3 Time-Dependent Multiconfi guration Methods for Multielectron Dynamics in Intense Laser Fields Takeshi Sato1, Kenichi L. Ishikawa1; 1University of Tokyo, Japan. ABSTRACT Time-dependent complete-active-space and general multiconfi guration self- consistent-fi eld methods are formulated. The concept of orbital subspacing in these methods enables compact yet accurate description of multielectron dynamics in intense laser fi elds.

07.Mon.P1.4 Phase-Matched Generation of High Order Harmonic for Study of Molecular dynamics Lap V. Dao1, Khuong B. Dinh1, Hoang L. Vu1, Peter Hannaford1; 1CAOUS, FSET, Swinburne University of Technology, Australia. ABSTRACT We present a pump-probe experiment based on the use of a second ﬁ eld to modulate the intensity and the spatial proﬁ le of the phase-matched high-order harmonics radiation for study of the dynamics of molecular gases. 15 ▶ TECHNICAL SESSIONS

07.Mon.P1.5

Ultrafast Photoelectron Spectroscopy of Electron-Ion Wave Packets in Rydberg N2 Mizuho Fushitani1, Yuto Toida1, François Légaré2, Akiyoshi Hishikawa1; 1Nagoya University, Japan; 2INRS, Energie, Matériaux et Télécommunication, Canada. MONDAY ABSTRACT Time-resolved photoelectron spectroscopy of N2 Rydberg using single-order high harmonics at 80 nm reveals ultrafast wavepacket + dynamics (~3 fs) of both Rydberg electron and the corresponding N2 core as the beating oscillation (~ 300 fs).

07.Mon.P1.6 Simultaneous Observation of Vibrational Wavepackets of Nitrogen Molecule in Neutral and Singly-charged Manifolds Tomoya Okino1, Yusuke Furukawa1, A. Amani Eilanlou1, Yasuo Nabekawa1, Eiji J. Takahashi1, Kaoru Yamanouchi2, Katsumi Midorikawa1; 1RIKEN, Japan; 2University of Tokyo, Japan. ABSTRACT Vibrational wavepackets are launched at neutral and single-charged electronic excited states of nitrogen molecule by sub-10 fs high harmonics. The evolution of vibrational wavepackets are tracked by sub-10 fs high harmonics.

07.Mon.P1.7 Tunneling channels in strong fi eld enhanced ionization of diatomic molecules Pengfei Lan1, Cheng Huang1, Yueming Zhou1, Qingbing Zhang1, Peixiang Lu1; 1Huazhong Univ. of Sci. & Tech., China. ABSTRACT We theoretically demonstrated two new ionization channels through which the electron can be released either from the down-fi eld or up-fi eld site of diatomic molecules. Our fi nding provides a comprehensive physical picture of molecular enhanced ionization.

07.Mon.P1.8 Correlation between photoelectron emission and fragment recoil of methanol in intense laser ﬁ elds Shinichi Fukahori1,2, Motoyoshi Nakano1, Kaoru Yamanouchi2, Ryuji Itakura1; 1Kansai Photon Science Institute, Japan Atomic Energy Agency, Japan; 2Department of Chemistry, School of Science, The University of Tokyo, Japan. ABSTRACT Dissociative ionization of methanol in an intense laser ﬁ eld is investigated using photoelectron-photoion coincidence momentum imaging. Energy and angular correlations between a photoelectron and a fragment ion reveal the ionization and subsequent electronic excitation processes.

07.Mon.P1.9

Laser induced rescattering photoelectron spectroscopy of CO2 molecule Misaki Okunishi1, Vandana Sharma2, Yuta Itoh1, Robert R. Lucchese3, Toru Morishita4, Oleg I. Tolstikhin5, Lars B. Madsen6, Kiyoshi Ueda1; 1IMRAM, Tohoku University, Japan; 2Department of Physics, IIT Hyderabad, India; 3Department of Chemistry, Texas A & M University, USA; 4Department of Engineering Science, University of Electro-Communications, Japan; 5Kurchatov Institute, Russian Federation; 6Department of Physics and Astronomy, Aarhus University, Denmark.

ABSTRACT We have measured rescattering photoelectron spectra of CO2 induced by ultrashort intense laser pulses at 1250 and 1300 nm and + extracted ﬁ eld-free differential cross sections of electron scattering from CO2 from the spectra.

07.Mon.P1.10 Real-time Probing of Ultrafast Hydrogen Migration in Methanol by Near-IR Few-cycle Laser Pulses Toshiaki Ando1, Akihiro Shimamoto1, Shun Miura1, Katsunori Nakai1, Huailiang Xu2, Atsushi Iwasaki1, Kaoru Yamanouchi1; 1Department of Chemistry, School of Science, University of Tokyo, Japan; 2College of Electronic Science and Engineering, Jilin University, China.

ABSTRACT Hydrogen migration in CH3OH was probed by pump-probe measurements using few-cycle laser pulses. Oscillation in the kinetic- + energy release of the fragment ions was interpreted theoretically as the motion of a migrating hydrogen atom in CH3OH .

07.Mon.P1.11 Generation of stationary on-axis optical ﬁ laments by means of Dammann lenses Jorge Pérez Vizcaíno1, Rocio Borrego-Varillas1,2, Omel Mendoza-Yero1, Glaldys Minguez-Vega1, Javier R. Vazquez de Aldana2, Jesus Lancis1; 1University Jaume I, Spain; 2Universidad de Salamanca, Spain. ABSTRACT Dynamical spatial shaping of a 30 fs laser beam by encoding Dammann lenses in a spatial light modulator allows us the formation up to six on-axis stable and stationary ﬁ laments in a fused silica sample. 16 TECHNICAL SESSIONS ▶

07.Mon.P1.12 A Regulation of Energy Flow in Purple Bacterial Photosynthetic Antennas MONDAY Daisuke Kosumi1, Satoshi Maruta1, Ritsuko Fujii1, Mitsuru Sugisaki1, Shinichi Takaichi3, Richard Cogdell2, Hideki Hashimoto1; 1Osaka City University, Japan; 2Nippon Medical School, Japan; 3University of Glasgow, United Kingdom. ABSTRACT Ultrafast energy transfer dynamics in photosynthetic antennas were investigated by femtosecond pump-probe measurements. Photo- excited carotenoids with short-polyene chains efﬁ ciently transfer energy to bacteriochlorophylls, while the energy rapidly dissipates to carotenoids in antennas containing longer carotenoids.

07.Mon.P1.13 Vibrational Energy Flow in Hemeproteins Yasuhisa Mizutani1, Naoki Fujii1, Mitsuhiro Miyamoto1, Misao Mizuno1, Haruto Ishikawa1; 1Osaka University, Japan. ABSTRACT We demonstrate that time-resolved anti-Stokes ultraviolet resonance Raman spectroscopy is a powerful tool for studying the vibrational energy ﬂ ow in proteins with a spatial resolution of an amino acid residue.

07.Mon.P1.14 Structural Motives of Acetic Acid from Ultrafast CARS Spectroscopy of the CO Vibration Matthias Lütgens1, Frank Friedriszik1, Stefan Lochbrunner1; 1Institute of Physics, University of Rostock, Germany. ABSTRACT The carbonyl vibration of acetic acid is analyzed by spontaneous and ultrafast coherent anti-Stokes Raman spectroscopy. The complex band is decomposed into four contributions from different structural motives and the cyclic dimer signature is extracted.

07.Mon.P1.15 2 Reconstruction of a Rotational Wave Packet Created in the X Π1/2 State of the NO Radical by a Nonresonant Intense Ultrashort Laser Pulse Hirokazu Hasegawa1, Yasuhiro Ohshima2; 1Department of Basic Science, The University of Tokyo, Japan; 2Institute for Molecular Science, Japan.

2 ABSTRACT We experimentally reconstructed a rotational wave packet created in NO(X Π1/2) by a nonresonant intense ultrashort laser ﬁ eld. The determined phase shifts show a clear signature of bifurcated pathways in the nonadiabatic rotational excitation.

07.Mon.P1.16 Natural Orbitals and Potential Curves within the Framework of Extended Multi-conﬁ guration Time-dependent Hartree-Fock Method Yoshihiro Ide1, Tsuyoshi Kato1, Kaoru Yamanouchi1; 1The University of Tokyo, Japan. ABSTRACT The extended multi-conﬁ guration time-dependent Hartree-Fock method is proposed to calculate time-dependent wave functions.

By constructing the ground-state wave function of one-dimensional H2 by imaginary time-propagation, the natural orbitals and the potential energy curves were derived.

07.Mon.P1.17 Ultrafast and Photodissociation Dynamics of 1,2-Butadiene Studied by Photoelectron Spectroscopy Ryo Iikubo1, Takehisa Fujiwara1, Taro Sekikawa1, Yu Harabuchi2, Tetsuya Taketsugu2; 1Applied Physics, Hokkaido University, Japan; 2Chemistry, Hokkaido University, Japan. ABSTRACT Ultrafast and photodissociation dynamics of a cumulated dine molecule, 1,2-butadiene, were investigated by time-resolved photoelectron spectroscopy using a high harmonic. In contrast with 1,3-butadiene, coherent oscillation by stimulated Raman process was observed prior to photodissociation.

07.Mon.P1.18 Ultrafast electronic structures and dynamics of CdSe nanocrystals revealed by gas phase time-resolved photoelectron spectroscopy Wei Xiong1, Daniel Hickstein1, Kyle Schnitzenbaumer2, Jennifer L. Ellis1, Brett B. Palm3, Chengyuan Ding1, Molly B. Beernink2, Gordana Dukovic2, Jose L. Jimenez3, Margaret Murnane1, Henry Kapteyn1; 1Department of Physics and JILA, University of Colorado and NIST, USA; 2Department of Chemistry and Biochemistry, University of Colorado, USA; 3Department of Chemistry and Biochemistry and CIRES, University of Colorado, USA.

17 ▶ TECHNICAL SESSIONS

ABSTRACT Using time-resolved photoelectron spectroscopy in a gas phase environment, we observed the evanescent electron wavefunction of quantum dot excited states, and the effect of solvent on QD charge transfer.

07.Mon.P1.19 MONDAY Coherent Wavepacket Motion in Ultrafast Intermolecular Electron Transfer in Electron-Donating Solvent Yusuke Yoneda1, Shohei Nambu1, Eisuke Takeuchi1, Yutaka Nagasawa1,2, Hiroshi Miyasaka1; 1Graduate School of Engineering Science, Osaka University, Japan; 2PRESTO, Japan Science and Technology Agency (JST), Japan. ABSTRACT Coherent wavepacket motion in an ultrafast electron transfer (ET) system consisting of electron accepting solute, 5,12-bis(phenylethynyl)-naphthacene and donating solvent, N,N-dimethylaniline was investigated by means of femtosecond transient absorption spectroscopy and excitation wavelength dependence was investigated.

07.Mon.P1.20 Detection of the G(-H)• Radical in the Electronic Deactivation of the G-C Watson-Crick Base Pair Katharina Röttger1, Friedrich Temps1; 1Institute of Physical Chemistry, Germany. ABSTRACT Transient absorption spectroscopy of the G-C base pair revealed the formation of the G(-H)• radical with lifetime 3 ps in the electronic deactivation. This radical is the key intermediate in an electron-coupled proton transfer.

07.Mon.P1.21 q+ Two-Step Explosion Dynamics of Highly Charged Fullerene Cations C60 (q = 20-60) Kaoru Yamazaki1, Takashi Nakamura1, Naoyuki Niitsu1,2, Manabu Kanno1, Kiyoshi Ueda3, Hirohiko Kono1; 1Department of Chemistry, Graduate School of Science, Tohoku University, Japan; 2Nanosystem Research Institute (NRI), National Institute of Advanced Industrial Science and Technology (AIST), Japan; 3Institute of Multidisciplinary Research for Advanced Materials, Tohoku University, Japan.

q+ z+ ABSTRACT C60 (q = 20-60) ﬁ rstly ejects fast atomic cations C (z ≥ 1) via Coulomb explosions on a 10 fs timescale. Thermal evaporations of slow atomic and molecular fragments subsequently occur in 100-1000 fs.

07.Mon.P1.22 Ultrafast Electron Solvation in Room Temperature Ionic Liquid/Metal Interfaces Alex Shearer1, Benjamin Caplins1, David Suich1, Charles Harris1; 1University of California Berkeley, USA.

+ - ABSTRACT The room temperature ionic liquid [Bmpyr] [NTf2] is studied on Ag(111). Monolayer and bilayer films both show a single state solvating, the timescale of solvation and magnitude of energy relaxation is signiﬁ cantly greater for the bilayer.

07.Mon.P1.23 Vibrational Dynamics of the CN Stretching in the Electronically Excited State by UV and Visible-Pump and Infrared-Probe Spectroscopy Sho Hiraoka1, Kaoru Ohta2, Keisuke Tominaga1,2; 1Chemistry, Graduate School of Science, Kobe University, Japan; 2Molecular Photoscience Research Center, Kobe University, Japan. ABSTRACT We have carried out visible-pump infrared-probe measurements on a CN-containing coumarin in a protic solvent. The time- dependent changes of the infrared spectra are measured on a picoseconds time scale, likely because of vibrational cooling.

07.Mon.P1.24 Microsecond Charge Recombination Lifetimes in Complexes of CdS Quantum Dots and Organic Hole Acceptors Enabled by Hole-Hopping within the Ligand Shell David J. Weinberg1, Zane Khademi1, Michal Malicki1, Seth Marder2, Emily Weiss1; 1Chemistry, Northwestern University, USA; 2Chemistry, Georgia Institute of Technology, USA. ABSTRACT Transient absorption (TA) and NMR measurements were used to demonstrate that carrier mobility within the ligand shell contributes to photoinduced charge transfer dynamics between a bis(diarylamino)biphenyl (TPD)-based thiol and cadmium sulﬁ de quantum dots.

07.Mon.P1.25 Ab Initio Quantum Dynamical Study on Ultrafast Nonradiative Transition Pathways of Pyrazine Manabu Kanno1, Yuta Ito2, Noriyuki Shimakura2, Shiro Koseki3, Hirohiko Kono1, Yuichi Fujimura1,4; 1Department of Chemistry, Graduate School of Science, Tohoku University, Japan; 2Department of Chemistry, Niigata University, Japan; 3Department of 18 TECHNICAL SESSIONS ▶

Chemistry, Graduate School of Science, Osaka Prefecture University, Japan; 4Department of Applied Chemistry, National Chiao-Tung

University, Taiwan. MONDAY

ABSTRACT We theoretically veriﬁ ed the participation of optically dark nπ* states other than S1 in ultrafast internal conversion of pyrazine. Contrary to a recent semiclassical study, our quantum dynamical calculations demonstrated that their contributions are negligible.

07.Mon.P1.26 Initial Phase in Quantum Beat Created via Ultrafast Internal Conversion of Pyrazine Yoshi-Ichi Suzuki1,2, Toshinori Suzuki1,2; 1Department of Chemistry, Gradiate School of Science, Kyoto University, Japan; 2RIEKN center for Advanced Photonics, RIKEN, Japan. ABSTRACT We present a simple interpretation for the phase-shifted quantum beat that is created on the lower electronic state from the higher state upon a nonradiative transition, using the classical mechanics and harmonic potentials.

07.Mon.P1.27 Ultrafast vibrational dynamics of water at a zwitterionic lipid/water interface revealed by two-dimensional heterodyne-detected vibrational sum frequency generation (2D HD-VSFG) Ken-ichi Inoue1, Prashant C. Singh1, Satoshi Nihonyanagi1,2, Shoichi Yamaguchi1, Tahei Tahara1,2; 1Molecular Spectroscopy Laboratory, RIKEN, Japan; 2Ultrafast Spectroscopy Research Team, RIKEN Center for Advanced Photonics (RAP), Japan. ABSTRACT 2D HD-VSFG is applied to the study of ultrafast vibrational dynamics at a zwitterionic lipid/water interface for the ﬁ rst time. The 2D spectrum reveals spectral diffusion of three distinct water species existing at the interface.

07.Mon.P1.28 Electronic Ground and Excited State Spectral Diffusion of a Photocatalyst Laura Kiefer1, John T. King1, Kevin J. Kubarych1; 1Chemistry, University of Michigan, USA. ABSTRACT Equilibrium and transient 2D IR spectroscopies were used to measure spectral diffusion of the electronic ground and excited states of the photocatalyst Re(bpy)(CO)3Cl. The ground state spectral diffusion decays 3 times faster than the 3MLCT.

07.Mon.P1.29 Nonlinear Carrier Responses in Gold Thin Films Induced by Intense Terahertz Waves Yasuo Minami1, Thang D. Dao2,3, Tadaaki Nagao2,3, Jun Takeda1, Masahiro Kitajima4,5, Ikufumi Katayama1; 1Yokohama National University, Japan; 2National Institute for Materials Science, Japan; 3CREST, Japan Science and Technology Agency, Japan; 4LxRay Co. Ltd., Japan; 5National Defense Academy, Japan. ABSTRACT Terahertz transmittances of the gold thin-films with thicknesses ranging from 1 to 12 nm were investigated. As terahertz field becomes intense, the transmittance of the terahertz ﬁ eld decreases, suggesting the increase of the carrier density.

07.Mon.P1.30 Ultrafast terahertz spectroscopy of rapid carrier relaxation in graphene oxide Jaeseok Kim1, Juyeong Oh2, Chihun In1, Yun-Shik Lee3, Theodore B. Norris4, Seong Chan Jun2, Hyunyong Choi1; 1School of Electrical and Electronic Engineering, Yonsei University, Republic of Korea; 2Department of Mechanical Engineering, Yonsei University, Republic of Korea; 3Department of Physics, Oregon State University, USA; 4Center for Ultrafast Optical Science and Department of Electrical Engineering and Computer Science, University of Michigan, Ann Arbor, USA. ABSTRACT We study the distinct terahertz (THz) carrier relaxation dynamics in graphene oxide (GO). In contrast to the graphene, we observe that the photoexcited carrier relaxation in GO exhibits a peculiar non-Drude behavior.

07.Mon.P1.31

Slow Electron Cooling Dynamics of Highly Luminescent CdSxSe1-x Alloy Quantum Dot Hirendra Ghosh1, Partha Maity1; 1Bhabha Atomic Research Centre, India.

ABSTRACT Ultrafast Electron cooling dynamics of highly luminescent oleic acid caped CdSxSe1-x alloy quantum dot (QD) is investigated by femtosecond transient absorption studies and found to much smaller as compared to pure CdSe and CdS Qds.

07.Mon.P1.32 Thickness dependent hot-phonon effects observed by femtosecond mid-infrared luminescence in graphene Tohru Suemoto1, Tomohiro Kawasaki1, Hiroshi Watanabe1; 1Institute of Solid State Physics, Japan. 19 ▶ TECHNICAL SESSIONS

ABSTRACT Femtosecond luminescence of graphene and graphite is studied from near- to mid-infrared regions. Remarkable reduction of lifetime at 0.3 eV in mono- and bi-layer graphenes is found, indicating carrier cooling due to interaction with substrate.

07.Mon.P1.33 MONDAY Snapshots of the retarded interaction of charge carriers with ultrafast ﬂ uctuations in cuprates Stefano Dal Conte1, Lev Vidmar2,3, Denis Golez3, Giancarlo Soavi1, Simone Peli4,5, Francesco Banfi4,6, Gabriele Ferrini4,6, Andrea Damascelli7,8, Daniele Brida1,9, Massimo Capone10, Janez Bonca3, Giulio Cerullo1, Claudio Giannetti6; 1Department of physics, IFN-CNR and Politecnico di Milano, Italy; 2Department of Physics and Arnold Sommerfeld Center for Theoretical Physics, Ludwig-Maximilians-Universitat, Germany; 3J. Stefan Institute, Slovenia; 4i-LAMP (Interdisciplinary Laboratories for Advanced Materials Physics), Italy; 5Department of physics, Università degli Studi di Milano, Italy; 6Department of physics, Università Cattolica del Sacro Cuore, Italy; 7Department of Physics and Astronomy, University of British Columbia, Canada; 8Quantum Matter Institute, Canada; 9Department of Physics and Center for Applied Photonics, University of Konstanz, Germany; 10CNR-IOM Democritos National Simulation Center and SISSA, Italy. ABSTRACT We measure the transient reflectivity of an high-Tc superconductor with an unprecedented temporal resolution (~15fs) demonstrating that on the 20-fs timescale electron dynamics is described in terms of charge carriers interacting with short-range antiferromagnetic ﬂ uctuations.

07.Mon.P1.34 Femtosecond time-resolved photoemission spectroscopy by using high-repetition rate Yb-ﬁ ber laser system Toshio Otsu1, Yukiaki Ishida1, Akira Ozawa1, Shik Shin1, Yohei Kobayashi1; 1ISSP, University of Tokyo, Japan. ABSTRACT Time-resolved photoemission spectroscopy using the 5th harmonic of a mode-locked, 95-MHz Yb-ﬁ ber laser enabled the detection of ultrafast electron dynamics in bismuth induced by a pump density as small as 30 nJ/mm2.

07.Mon.P1.35 Mid-IR Pump, EUV Probe Femtosecond Time-and-Angle-Resolved Photoemission Spectroscopy Cephise Cacho1, Jesse Petersen2,3, Isabella Gierz3, Haiyun Liu3, Stefan Kaiser3, Richard Chapman1, Edmond Turcu1, Andrea Cavalleri2,3, Emma Springate1; 1STFC Rutherford Appleton Laboratory, United Kingdom; 2Department of Physics, University of Oxford, United Kingdom; 3Max Planck Institute for the Structure and Dynamics of Matter, Germany. ABSTRACT Using EUV high harmonic probe in time- and angle-resolved photoemission spectroscopy extends the energy and momentum observation window for studies of electron dynamics in condensed matter, while tunable mid-infrared pumping allows control of excitation mechanisms.

07.Mon.P1.36 Ultrafast carriers dynamics in silicon: a joint experimental and theoretical study Stefano Dal Conte1, Davide Sangalli2, Andrea Marini2, Giulio Cerullo1, Cristian Manzoni1; 1IFN-CNR, Department of Physics, Politecnico di Milano, Italy; 2Istituto di Struttura della Materia of the National Research Council, Monterotondo Stazione, Italy. ABSTRACT We investigate the carriers dynamics in bulk silicon using pump-probe spectroscopy. The experimental results are compared with theoretical calculations which combines for the ﬁ rst time the non-equilibrium Green’s functions theory with ab-initio methods.

07.Mon.P1.37 Polarization State Changes of Femtosecond, Polarization-shaped Pulsed Beams on Free Space Propagation Balazs Major1, Miguel A. Porras2, Attila P. Kovacs1, Zoltan L. Horvath1; 1Department of Optics and Quantum Electronics, University of Szeged, Hungary; 2Departamento de Fisica Aplicada a los Recursos Naturales and Grupo de Sistemas Complejos, Universidad Politecnica de Madrid, Spain. ABSTRACT We show that free space propagation of polarization-shaped pulsed beams induces substantial changes in their polarization state. The physical origin of this effect, its theoretical description, and classical polarization measurements reﬂ ecting this phenomenon, are presented.

07.Mon.P1.38 Ultrafast Spin Dynamics in an Antiferromagnet NiO Observed in Pump-Probe and Terahertz Experiments Takeshi Moriyasu1, Toshiro Kohmoto1; 1Kobe University, Japan. ABSTRACT We observed the ultrafast spin dynamics in an antiferromagnet NiO. The dynamics of the antiferromagnetic magnons and the 20 magnetostriction was studied using the pump-probe technique and THz-TDS. TECHNICAL SESSIONS ▶

07.Mon.P1.39 Ultrafast control of electron-phonon entangled systems in bulk solids MONDAY Yosuke Kayanuma1; 1Tokyo Institute of Technology, Japan. ABSTRACT A simple theory is presented for the ultrafast coherent control of electron-phonon entangled systems in condensed matter which agrees well with the transient reﬂ ectivity measurement by the sub-femtosecond phase-locked dual pulse technique in bulk GaAs.

07.Mon.P1.40 Spontaneous formation of correlated charge coherence induced by

1.5-cycle pulse in 1-D organic metal (TMTTF)2AsF6 Takahiro Ishikawa1, Yuto Sagae1, Yohei Kawakami1, Hirotake Itoh1,2, Kaoru Yamamoto3, Kyuya Yakushi4, Sumio Ishihara1, Takahiko Sasaki5,2, Kenji Yonemitsu6, Shinichiro Iwai1,2; 1Physics, Tohoku University, Japan; 2CREST, JST, Japan; 3Applied Physics, Okayama Science University, Japan; 4Toyota Physical and Chemical Research, Japan; 5Institute for Materials Research, Tohoku University, Japan; 6Physics, Chuo University, Japan.

ABSTRACT Ultrafast response of (TMTTF)2AsF6 induced by 1.5 cycle (7 fs) infrared pulse was investigated. Coherent oscillation of correlated charge (18 fs) grows in the time scale of 50 fs, reflecting the spontaneous-formation of the electronic coherence before the electronic thermalization

07.Mon.P1.41 Phase Transitions in Co-Doped NiMnGa Magnetic Shape Memory Alloys Probed by Coherent Phonons Thomas Dekorsy1, Martin Schubert1, Jan Mayer1, Mike Hettich1, Hanjo Schäfer1, Alexej Laptev1, Moritz Merklein1, Chuan He1, Martin Grossmann1, Oliver Ristow1, Yuanson Luo2, Vitalyi Gusev3, Jure Demsar1, Mikhail Fonin1, Konrad Samwer2; 1Universitat Konstanz, Germany; 2University Goettingen, Germany; 3Université du Maine, France. ABSTRACT We investigate undoped and Co-doped NiMnGa magnetic shape memory alloys by ultrafast spectroscopy. The temperature dependence of collective modes is explained on the base of a charge-density-wave excitation shining new light on the phase transition.

07.Mon.P1.42 Electrochemical Control of Coherent Phonon Generations in Single-walled Metallic Carbon Nanotubes Keisuke Maekawa1, Kenji Sato1, Yasuo Minami1, Ikufumi Katayama1, Jun Takeda1, Kazuhiro Yanagi2, Masahiro Kitajima3,4; 1Yokohama National University, Japan; 2Department of Physics, Tokyo Metropolitan University, Japan; 3LxRay Co. Ltd., Japan; 4Department of Applied Physics, National Defense Academy, Japan. ABSTRACT Coherent phonons in single-walled metallic carbon nanotubes were measured under the application of a gate voltage through ionic liquid. We found that the frequencies, amplitudes and phases of the phonons strongly depend on the voltage.

07.Mon.P1.43 Ultrabroadband infrared pump-probe spectroscopy using chirped-pulse upconversion Hideto Shirai1, Tien-Tien Yeh2, Yutaka Nomura1, Chih Wei Luo2, Takao Fuji1; 1Institute for Molecular Science, Japan; 2Department of Electrophysics, National Chiao Tung University, Taiwan. ABSTRACT We have demonstrated infrared pump-probe spectroscopy using chirped-pulse upconversion with a nonlinear mixing in a gas. Ultrafast dynamics of free carrier in Ge was clearly observed in the range 200-5000 cm-1.

07.Mon.P1.44

Ultrafast Phonon Dynamics in Few-quintuple layer Topological Insulator Sb2Te 3 Katsura Norimatsu1,2, Shin-ichi Uozumi1,2, Shingo Hayashi1,2, Kyushiro Igarashi1, Shuhei Yamamoto1, Takao Sasagawa1, Kazutaka Nakamura1,2; 1Tokyo Institute of Technology, Japan; 2JST-CREST, Japan.

2 ABSTRACT We found few-quintuple layer Sb2Te 3 presents the in-plane coherent oscillation (Eg mode) using time-resolved transmission 1 2 measurements, which is different from the results, out-of-plane oscillations (A1g and A1g modes) obtained in bulk.

07.Mon.P1.45 A compact MHz high-harmonic light source for efﬁ cient laboratory photoemission spectroscopy Andreas Trützschler1,2, Michael Huth1, Cheng-Tien Chiang1,2, Frank O. Schumann1, Jürgen Kirschner1,2, Wolf Widdra2,1; 1MPI of Microstructure Physics, Germany; 2Institute of Physics, Martin-Luther-Universitaet Halle-Wittenberg, Germany. 21 ▶ TECHNICAL SESSIONS

ABSTRACT We demonstrate high-order harmonic generation driven by a compact fiber laser as a light source for efficient photoemission spectroscopy, which allows mapping of the dominant part of the valence band of Ag(100) within 10 seconds.

07.Mon.P1.46 MONDAY Investigation on Dynamics of Nano-Plasma of Rare-Gas Clusters by EUVFEL Pump - NIR Laser Probe Measurements Kiyonobu Nagaya1,2, Tsukasa Sakai1, Toshiyuki Nishiyama1, Kenji Matsunami1, Satoshi Yase1, Makoto Yao1, Hironobu Fukuzawa2,3, Koji Motomura3, Tetsuya Tachibana3, Subhendu Mondal3, Kiyoshi Ueda2,3, Shin-ichi Wada2,4, Hironori Hayashita4, Norio Saito2,5, Tadashi Togashi2,6, Mitsuru Nagasono2, Makina Yabashi2; 1Department of Physics, Kyoto University, Japan; 2SPring-8 Center, RIKEN, Japan; 3Institute of Multidisciplinary Research for Advanced Materials, Tohoku University, Japan; 4Department of Physical Science, Hiroshima University, Japan; 5National Metrology Institute of Japan, AIST, Japan; 6Japan Synchrotron Radiation Research Institute, Japan. ABSTRACT Via extreme ultraviolet free electron laser pump and near infrared laser probe experiments for rare-gas clusters, we found clear enhancement of highly charged ions when EUVFEL and NIR pulses overlap, indicating efﬁ cient heating of nano-plasma

07.Mon.P1.47

Enhancement of superconducting coherence in YBa2Cu3Ox by resonant lattice excitation Daniele Nicoletti1, Wanzheng Hu1, Stefan Kaiser1, Cassandra R. Hunt1, Isabella Gierz1, Mathieu Le Tacon2, Toshinao Loew2, Bernhard Keimer2, Andrea Cavalleri1,3; 1Max Planck Institute for the Structure and Dynamics of Matter, Germany; 2Max Planck Institute for Solid State Research, Germany; 3Department of Physics, Clarendon Laboratory, Oxford University, United Kingdom. ABSTRACT By using femtosecond pulses in the mid-infrared, we resonantly excite an infrared-active phonon mode in the high-temperature

superconductor YBa2Cu3Ox. The electronic properties of the driven state, probed with ultra-broadband time-domain terahertz spectroscopy, are highly unconventional.

07.Mon.P1.48 Controlling coherent energy ﬂ ow between collective THz excitations in condensed matter Tobia Nova1, Andrea Cartella1, Alice Cantaluppi1, Rostislav Mikhaylovskiy2, Ilya Razdolski2, Michael Först1, Alexey Kimel2, Andrea Cavalleri1,3; 1Max Planck Institute for the Structure and Dynamics of Matter, Germany; 2Radboud University, Netherlands; 3Oxford University, United Kingdom.

ABSTRACT Coherent control over the magnetization state of the rare-earth orthoferrite ErFeO3 is achieved by nonlinear lattice excitation via mid- infrared laser pulses. This low-dissipative approach enables new pathways in light-driven manipulation of magnetic materials.

07.Mon.P1.49 Strong-Field-Enhanced Forward Scattering of High-Order Harmonics Carles Serrat1; 1Universitat Politecnica de Catalunya, Spain. ABSTRACT We show that scattering of ultrashort XUV pulses from strong-ﬁ eld driven electron wavepackets is enhanced as compared with normal weak scattering from bound or free electrons. We predict large XUV ampliﬁ cation in high-order harmonic generation.

07.Mon.P1.50 Improvement for HHG-seeded EUV Free Electron Laser with Timing Measurement System by EO Sampling Kanade Ogawa1, Takahiro Sato5, Shigeki Owada1, Shinichi Matsubara2, Yuichi Okayasu2, Tadashi Togashi2, Takahiro Watanabe1,2, Eiji J. Takahashi3, Katsumi Midorikawa3, Makoto Aoyama4, Koichi Yamakawa4, Atsushi Iwasaki5, Kaoru Yamanouchi5, Takashi Oshima1,2, Yuji Otake1,2, Toru Hara1,2, Takashi Tanaka1,2, Hitoshi Tanaka1,2, Hiromitsu Tomizawa1,2, Makina Yabashi1,2, Tetsuya Ishikawa1; 1RIKEN, Japan; 2Japan Synchrotron Radiation Research Institute, Japan; 3RIKEN Advanced Science Institute, Japan; 4Japan Atomic Energy Agency, Japan; 5The University of Tokyo, Japan. ABSTRACT Using the arrival timing measurement system based on EO (Electro-Optic) sampling technique, we improved the number of successful seeded FEL. HHG-seeded FEL was operated over half a day with a 20-30 % effective hit rate.

07.Mon.P1.51 Arrival-timing diagnostics for pump-probe experiments in SACLA using X-ray-induced optical transparency in GaAs Tadashi Togashi1,2, Takahiro Sato2,3, Kanade Ogawa2, Tetsuo Katayama1,2, Shigeki Owada2, Yuichi Inubushi1,2, Kensuke Tono1,2, Makina Yabashi2,1; 1XFEL Utilization Division, Japan Synchrotron Radiation Research Institute, Japan; 2SPring-8 Center, 22 TECHNICAL SESSIONS ▶

RIKEN, Japan; 3The University of Tokyo, Japan.

ABSTRACT We have developed an arrival-timing monitor between XFEL and optical laser pulses in SACLA by using X-ray-induced optical MONDAY transparency in GaAs. We have evaluated the timing jitter to be 130 fs with 10 fs resolution.

07.Mon.P1.52 Collinear two dimensional infrared spectroscopy with a phase-locked pulse pair delayed by a birefringent delay line Julien Rehault1, Margherita Maiuri1, Cristian Manzoni1, Daniele Brida2, Jan Helbing3, Giulio Cerullo1; 1Dipartimento di Fisica, Politecnico di Milano, Italy; 2Department of Physics and Center for Applied Photonics, University of Konstanz, Germany; 3Department of Chemistry, University of Zurich, Switzerland. ABSTRACT We perform two dimensional spectroscopy in the mid-IR by using a set of birefringent wedges to generate and delay a phase-locked pair of pump pulses.

07.Mon.P1.53 Generation of Isolated Soft X-Ray Pulses Around the Carbon K-Edge Using CEP-Stabilized Few-Cycle IR Pulses Nobuhisa Ishii1, Keisuke Kaneshima1, Kenta Kitano1, Teruto Kanai1, Shuntaro Watanabe2, Jiro Itatani1; 1Institute for Solid State Physics, Japan; 2Tokyo University of Science, Japan. ABSTRACT We demonstrate the generation of a 75-eV-wide continuum in the water window via HHG using CEP-stabilized, few-cycle IR pulses. A pressure dependence of harmonic spectra indicates sub-cycle deformation of IR pulses in the HHG process.

07.Mon.P1.54 High ﬂ ux coherent supercontinuum soft X-ray source driven by a single-stage Ti:sapphire-pumped OPA Chengyuan Ding1, Wei Xiong1, Tingting Fan1, Daniel Hickstein1, Tenio Popmintchev1, Xiaoshi Zhang2, Mike Walls2, Margaret Murnane1, Henry Kapteyn1; 1JILA and Physics, University of Colorado at Boulder, USA; 2Kapteyn-Murnane Laboratories, USA. ABSTRACT We demonstrate the highest flux tabletop coherent soft X-ray source to date, using high harmonics driven by a single-stage Ti:sapphire-pumped OPA at 1.3µm. The spectrum extends to 200eV, with a ﬂ ux of >106 photons/pulse/1% bandwidth.

07.Mon.P1.55 High-Energy Sub-Optical-Cycle Parametric Waveform Synthesizer Giovanni Cirmi1,3, Giulio Rossi1,3, Shaobo Fang1,3, Shih-Hsuan Chia1,3, Oliver D. Mücke1,3, Cristian Manzoni5, Paolo Farinello5, Giulio Cerullo5, Franz X. Kärtner2,4; 1Center for Free-Electron Laser Science, Deutsches Elektronen-Synchrotron DESY, Germany; 2Physics Department, University of Hamburg, Germany; 3The Hamburg Center for Ultrafast Imaging, Germany; 4Department of Electrical Engineering and Computer Science and Research Laboratory of Electronics, Massachusetts Institute of Technology, USA; 5IFN-CNR, Dipartimento di Fisica, Politecnico di Milano, Italy. ABSTRACT We present FROG characterization of all three spectral channels of a multi-ampliﬁ cation-stage sub-optical-cycle parametric waveform synthesizer covering more than two octaves in bandwidth. The compressed 0.4-mJ energy can be scaled to the multi-mJ level.

07.Mon.P1.56 Direct Generation of 7 fs Whitelight Pulses from Bulk Sapphire Emanuel Wittmann1, Maximilian Bradler1, Eberhard Riedle1; 1Ludwig Maximilians Universität München, Germany. ABSTRACT Generation of sub-10 fs continuum pulses without external compression is demonstrated. We investigate the propagation of the newly generated wavelengths and ﬁ nd that a short crystal in combination with an achromatic telescope leads to nearly chirp free continua.

07.Mon.P1.57 [Canceled]

07.Mon.P1.58 Passively CEP-Stable front end for frequency synthesis Huseyin Cankaya1,2, Anne-Laure Calendron1,2, Franz X. Kärtner1,3; 1Ultrafast Optics and X-Rays Division, CFEL DESY, Germany; 2The Hamburg Centre for Ultrafast Imaging, Universität Hamburg, Germany; 3Department of Electrical Engineering and Computer Science and Research Laboratory of Electronics, Massachusetts Institute of Technology, USA. 23 ▶ TECHNICAL SESSIONS

ABSTRACT We demonstrate a passive CEP-stable two-octave wide front-end for a high-energy optical waveform synthesizer driven by slightly sub-picosecond pump pulses from a multi-mJ regenerative ampliﬁ er.

07.Mon.P1.59 MONDAY Towards a Compact Fiber Laser for Multimodal Imaging Ilyas Saytashev1, Bai Nie2, Marcos Dantus1,2; 1Department of Chemistry, Michigan State University, USA; 2Department of Physics and Astronomy, Michigan State University, USA. ABSTRACT We report on multimodal depth-resolved imaging of unstained living Drosophila Melanogaster larva using sub-50 fs pulses centered at 1060 nm wavelength. Both second harmonic and third harmonic generation imaging modalities are demonstrated.

07.Mon.P1.60 X-rays from quasi-phase-matched high-harmonic generation Emeric Balogh1, Katalin Varjú1; 1Department of Optics and Quantum Electronics, University of Szeged, Hungary. ABSTRACT Extension of high-order harmonic cutoff in quasi-phase-matched environment is proposed, using low-intensity, counterpropagating pulses in the NIR and MIR regime. We calculate the optimal ﬁ eld parameters, bandwidth and possible cutoff extension of the generated radiation.

Room A 17:15-19:00 07.Mon.E Condensed Phase Dynamics Presider: Shaul Mukamel (University of California at Irvine, United States)

07.Mon.E.1 17:15 Invited Ultrafast Vibrational Spectroscopy at Liquid Interfaces by Heterodyne-Detected Sum-Frequency Generation Tahei Tahara1,2; 1Molecular Spectroscopy Laboratory, RIKEN, Japan; 2RIKEN Center for Advanced Photonics, RIKEN, Japan. ABSTRACT Ultrafast dynamics at liquid interfaces are still obscure. Femtosecond time-resolved heterodyne-detected vibrational sum-frequency generation spectroscopy now enables us to investigate vibrational/photochemical dynamics at liquid interfaces with the same clarity as in solution- phase ultrafast spectroscopy.

07.Mon.E.2 17:45 Contributed Hydrated Phospholipid Surfaces Probed by Ultrafast 2D Spectroscopy of Phosphate Vibrations Thomas Elsaesser1, Rene Costard1, Ismael A. Heisler1; 1Max Born Institute, Germany. ABSTRACT Phosphate stretching vibrations probe interfacial dynamics in hydrated phospholipids. Two-dimensional spectra in the 1000-1300 cm-1 range reveal structural ﬂ uctuations on a 300 fs time scale while water-phosphate hydrogen bonds persist for longer than 10 ps.

07.Mon.E.3 18:00 Contributed Detecting the Infl uence of Ions on Protein Hydration Dynamics with Site-Specifi c 2D-IR John T. King1, Evan J. Arthur1, Charles L. Brooks1, Kevin J. Kubarych1; 1Chemistry, University of Michigan, USA. ABSTRACT A strong vibrational probe bound to the surface of the model protein lysozyme reveals ion-specifi c modulation of the local hydration dynamics. Explicit water and ion simulations reveal strong cation association with a nearby charged side-chain.

07.Mon.E.4 18:15 Contributed Femtosecond Time and Angle Resolved Photoemission Spectroscopy of Liquids Yo-Ichi Yamamoto1,2, Yoshi-Ichi Suzuki1,2, Toshinori Suzuki1,2; 1Chemistry, Kyoto University, Japan; 2RIKEN, Japan. ABSTRACT We report the ﬁ rst time and angle resolved photoemission spectroscopy of liquids using a time-of-ﬂ ight photoelectron spectrometer and a sub MHz deep ultraviolet femtosecond laser.

07.Mon.E.5 18:30 Contributed Bimolecular Reactions on a Timescale below 1 ps Roland Wilcken1, Herbert Mayr2, Eberhard Riedle1; 1Chair for BioMolecular Optics, Ludwig-Maximilians-University Munich, 24 TECHNICAL SESSIONS ▶

Germany; 2Department for Chemistry, Ludwig-Maximilians-University Munich, Germany.

ABSTRACT Access to the intrinsic reaction rate is gained by canceling out diffusion. The use of precursors on demand and reactive MONDAY solvents allows the study of reactions down to 220 fs. Even the molecular rotation is considerably slower and a preformed, favorable configuration is concluded.

07.Mon.E.6 18:45 Contributed Vibrational Dynamics of Nitrosyl Stretch of Ru Complex in Aqueous Solution Studied by Two-Dimensional Infrared Spectroscopy Kaoru Ohta1, Kyoko Aikawa2, Keisuke Tominaga1,2; 1Molecular Photoscience Research Center, Kobe University, Japan; 2Graduate School of Science, Kobe University, Japan.

2- ABSTRACT Vibrational frequency ﬂ uctuation of NO stretch of [RuCl5(NO)] in water was studied by two-dimensional infrared spectroscopy. Observed temperature dependence provides evidence that collective dynamics of hydrogen bonding network controls the time scale of frequency ﬂ uctuation.

25 ▶ TECHNICAL SESSIONS

Tuesday, July 8

Room A 08:30-10:15 08.Tue.A Attosecond Electron Dynamics Presider: Louis DiMauro (Ohio State University, United States)

08.Tue.A.1 08:30 Invited

TUESDAY Ultrafast Laser Control of Absorption and Emission via the Fano Phase Thomas Pfeifer1; 1Quantum Dynamics, Max-Planck-Institut fur Kernphysik, Germany. ABSTRACT Transmission of attosecond-pulsed light through Helium gas driven by few-cycle laser ﬁ elds of tunable intensity allows to temporally resolve and control the process of absorption. The results enabled the understanding of Fano resonances in the time domain and corresponding scientiﬁ c applications.

08.Tue.A.2 09:00 Contributed Attosecond dynamics of autoionizing states in electronic molecular wave packets Maurizio Reduzzi1, Wei-Chun Chu2, Chengyong Feng1, Antoine Dubrouil1, Johan Hummert1, Francesca Calegari3, Fabio Frassetto4, Luca Poletto4, Oleg Kornilov5, Mauro Nisoli1,3, Chii Dong Lin2, Giuseppe Sansone1,3; 1Physics, Politecnico di Milano, Italy; 2Physics, Kansas State University, USA; 3Institute of Photonics and Nanotechnologies, IFN-CNR, Italy; 4Institute of Photonics and Nanotechnologies, IFN-CNR, Italy; 5Max-Born-Institut, Germany. ABSTRACT By combining an isolated attosecond pulse and a few-cycle infrared ﬁ eld, we resolve in time the autoionization dynamics of two series of Fano resonances in nitrogen.

08.Tue.A.3 09:15 Contributed Sub-4-fs Charge Migration in Phenylalanine Francesca Calegari1, David Ayuso2, Louise Belshaw3, Andrea Trabattoni4, Sunilkumar Anumula4, Simone De Camillis3, Fabio Frassetto5, Luca Poletto5, Alicia Palacios2, Piero Decleva6, Jason Greenwood3, Fernando G. Martin2,7, Mauro Nisoli4,1; 1IFN- CNR, Italy; 2Universidad Autonoma de Madrid, Spain; 3Queen’s University Belfast, United Kingdom; 4Politecnico di Milano, Italy; 5IFN-CNR, Italy; 6Università di Trieste, Italy; 7Instituto Madrileno de Estudios Avanzados en Nanociencia, Spain. ABSTRACT Charge migration initiated by attosecond pulses was experimentally observed in an amino-acid. An oscillatory pattern in the yield of a doubly-charged fragments was measured with periods of 3.7 fs and 2.6 fs.

08.Tue.A.4 09:30 Contributed Pump-probe photoelectron imaging with 90-nm excitation pulses Shunsuke Adachi1,2, Motoki Sato1, Yoshi-Ichi Suzuki1, Toshinori Suzuki1,2; 1Department of chemistry, Graduate school of Science, Kyoto University, Japan; 2RIKEN Center for Advanced Photonics, RIKEN, Japan. ABSTRACT Pump-probe photoelectron imaging was performed with 90-nm excitation pulses. Quantum beat by coherent excitation of multiple

Rydberg states in Kr, and photodissociation of CO2 within a few ps from initially excited Rydberg state(s) were observed.

08.Tue.A.5 09:45 Contributed XUV pump-XUV probe studies of 1fs scale dynamics in atoms and molecules Dimitrios Charalambidis1,2, Paraskevas Tzallas1, Emmanouil Skantzakis1, Alicia Palacios3, David Gray1, Fernando G. Martin3,4, Poalo Antonio Carpeggiani1,2; 1FORTH-IESL, Greece; 2Physics Department, Univ. of Crete, Greece; 3Departamento de Química, Módulo 13, Universidad Autónoma de Madrid, Spain; 4Instituto Madrileño de Estudios Avanzados en Nanociencia, Spain. ABSTRACT Exploiting intense coherent XUV continua, supporting attosecond pulse formation, we have performed the ﬁ rst ever XUV-pump-XUV- probe studies of 1fs scale dynamics in atoms and molecules. Progress towards single shot non-linear XUV autocorrelation is also reported.

08.Tue.A.6 10:00 Contributed Multiphoton Transitions for Robust Delay-Zero Calibration in Attosecond Transient Absorption Jens Herrmann1, Matteo Lucchini1, Shaohao Chen2, Mengxi Wu2, André Ludwig1, Lamia Kasmi1, Kenneth J. Schafer 2, Lukas Gallmann 1,3, Mette B. Gaarde2, Ursula Keller1; 1ETH Zurich, Switzerland; 2Louisiana State University, USA; 3University of Bern, Switzerland. ABSTRACT We present a novel in-situ method for the delay-zero calibration in attosecond transient absorption experiments. Our method is based 26 on oscillations on the sub-femtosecond timescale originating from multiphoton transitions. TECHNICAL SESSIONS ▶

Room A 10:45-12:30 Room B 10:45-12:30

08.Tue.B Nanotips and 08.Tue.C Biology Nanooptics Presider: Erik T.J. Nibbering (Max Born Institute, Germany) Presider: Walter Pfeiffer (Zephyr Photonics, Germany) TUESDAY

08.Tue.B.1 10:45 Contributed 08.Tue.C.1 10:45 Contributed Visualization of Photocurrents in Nanoobjects Coherence in Oxygenic Photosynthesis by Ultrafast Low-Energy Electron Franklin D. Fuller1, Jie Pan1, Andrius Gelzinis2,3, Vytautas Point-Projection Imaging Butkus2,3, Seckin Senlik1, Daniel E. Wilcox1, Leonas 2,3 2 1 Melanie Müller1, Alexander Paarmann1, Ralph Ernstorfer1; Valkunas , Darius Abramavicius , Jennifer P. Ogilvie ; 1 1Physical Chemistry, Fritz-Haber-Institut der Max-Planck- Physics and Biophysics, University of Michigan, USA; 2 Gesellschaft, Germany. Ultrafast dynamics of photocurrents in Department of Theoretical Physics, Vilnius University, 3 semiconductor nanowires are investigated with femtosecond time Lithuania; Center for Physical Sciences and Technology, Vilnius and nanometer spatial resolution. University, Lithuania. ABSTRACT We demonstrate the capability of time-resolved low- ABSTRACT We report coherent dynamics in the photosystem II energy electron point-projection imaging as a novel tool for mapping reaction center observed by two dimensional electronic spectroscopy. transient ﬁ elds at nanostructures. We discuss the physical nature of the coherences and their importance for charge separation.

08.Tue.B.2 11:00 Contributed 08.Tue.C.2 11:00 Contributed Control of Femtosecond Surface Plasmon Coupled onto a Gold Tapered Tip and Following the Excited State Dynamics of its Nonlinear Emission β-apo-8’-carotenal with Two-Dimensional Electronic-Vibrational Spectroscopy Kazunori Toma1, Yuta Masaki1, Kenichi Hirosawa1, Fumihiko 1 1 1 Kannari1; 1Keio University, Japan. Thomas Oliver , Nicholas Lewis , Graham R. Fleming ; 1Chemistry, UC Berkeley, USA. ABSTRACT Spatiotemporal nanofocusing of surface plasmon polariton excited by femtosecond laser pulses on a sharp ABSTRACT Two-dimensional electronic-vibrational spectroscopy conical Au tip with a tip edge radius of few tens of nanometers is is used to study the excited state evolution of the carotenoid β-apo- deterministically controlled. 8’-carotenal in solution. This new multidimensional spectroscopy is unique in its ability to directly follow the electronic and nuclear degrees of freedom simultaneously. 08.Tue.B.3 11:15 Contributed

Ultrafast optical-ﬁ eld controlled photoemission 08.Tue.C.3 11:15 Contributed from plasmonic nanoparticle arrays Ultrafast Interaction of Dark and 1 1 1 William Putnam , Richard Hobbs , Yujia Yang , Karl Bright Electronic States in Open-Chain Berggren1, Franz Kaertner1,2; 1Department of Electrical Carotenoids Investigated by Pump-DFWM Engineering and Computer Science and Research Laboratory 1 1 1 of Electronics, Massachusetts Institute of Technology, USA; Takeshi Miki , Tiago Buckup , Marie Marek , Richard 2 1 1 2Center for Free-Electron Laser Science, DESY and Department Cogdell , Marcus Motzkus ; Physikalisch-Chemisches Institut, 2 of Physics, University of Hamburg, Germany. Heidelberg University, Germany; Institute of Biomedicine & Life Science, University of Glasgow, United Kingdom. ABSTRACT Exciting plasmonic nanoparticles with two-cycle optical pulses, we observe photoemission across few-micron gaps under ABSTRACT Coupling between dark and bright electronic states ambient conditions. The photoemission is modulated by the carrier- in carotenoids was observed in the ultrafast evolution of vibrational envelope phase with a signal-to-noise ratio exceeding 20 dB at 1 Hz coherence and in the non-oscillatory signal of pump-DFWM. Coupling resolution-bandwidth. efﬁ ciency depends on the number of conjugated double bonds.

08.Tue.B.4 11:30 Contributed 08.Tue.C.4 11:30 Contributed Photoelectron Emission from Disentangling Electronic and Resonant Nanoantennas Driven by Vibrational Coherence in the Phycocyanin-645 Femtosecond Mid-infrared Pulses Light-Harvesting Complex 1 2 2 Fumiya Kusa1, Katharina Echternkamp2, Georg Herink2, Gethin H. Richards , Krystyna E. Wilk , Paul M. Curmi , 1 1 Claus Ropers2, Satoshi Ashihara1; 1Applied Physics, Tokyo Jeffrey A. Davis ; Swinburne University of Technology, 2 Univ of Agriculture and Technology, Japan; 2IV. Physikalisches Australia; University of New South Wales, Australia. Institut, University of Goettingen, Germany. ABSTRACT We selectively excite coherence pathways in the light- 27 ▶ TECHNICAL SESSIONS

ABSTRACT Strong-fi eld photoelectron emission from gold nanorod harvesting complex PC645 and with wavelength and polarization antennas induced by mid-infrared pulses is studied using time-of-fl ight control identify contributions from both electronic and vibrational spectroscopy. The emission and acceleration of photoelectrons are coherences. Insight into the interactions between excited electronic and maximized at the half-wave antenna resonance, evidencing substantial vibrational states follows. near-fi eld enhancements.

08.Tue.C.5 11:45 Contributed 08.Tue.B.5 11:45 Contributed Ultrafast Energy Flow and Equilibration THz-Controlled Photoelectron Emission Dynamics in Photosynthetic from Nanotips Light-Harvesting Complexes 1 1 1 Lara Wimmer , Georg Herink , Katharina Echternkamp , Margherita Maiuri1, Larry Luer2, Sarah Henry3, Anne-Marie

TUESDAY 1 1 1 1 Sergey Yalunin , Daniel R. Solli , Max Gulde , Claus Ropers ; Carey3, Richard Cogdell3, Giulio Cerullo1, Dario Polli1; 1IFN- 1 4. Physical Institute, University of Goettingen, Germany. CNR, Dipartimento di Fisica, Politecnico di Milano, Italy; 2 ABSTRACT We introduce terahertz gating and streaking of Department of Nanoscience, Madrid Institute for Advanced photoelectron emission at a single nanostructure. The THz-near- Studies, Spain; 3University of Glasgow, United Kingdom. field enhancement allows for far-reaching electron trajectory control, ABSTRACT We disentangle various energy transfer pathways including phase-resolved streaking by the momentary THz field and in the bacterio-chlorophyll excitation cascade from LH2 to LH1 propagation-induced spectral reshaping. in Chromatium vinosum grown under high-light or low-light illumination using tunable narrowband selective excitation and broadband infrared probing. 08.Tue.B.6 12:00 Invited Terahertz STM for imaging ultrafast nanoscale dynamics 08.Tue.C.6 12:00 Contributed Tyler Cocker1, Vedran Jelic1, James Hoffman1, Manisha Ultrafast Energy Transfer in Gupta2, Reginald Miller1, Sean Molesky2, Jacob Burgess1, LH2 Photosynthetic Antenna Conjugated with Glenda De Los Reyes1, Lyubov Titova1, Ying Tsui2, Mark Artiﬁ cial Fluorescent Dyes 1 1 1 Freeman , Frank A. Hegmann ; Physics, University of Alberta, Yutaka Nagasawa1,3, Yusuke Yoneda1, Tetsuro Katayama3, 2 Canada; Electrical and Computer Engineering, University of Hiroshi Miyasaka1,4, Naoto Mizutani2, Tomoyasu Noji2, Alberta, Canada. Takehisa Dewa2; 1Graduate School of Engineering Science, ABSTRACT A new ultrafast technique that couples terahertz Osaka University, Japan; 2Department of Life and Materials pulses to the tip of a scanning tunneling microscope (THz-STM) and Engineering, Nagoya Institute of Technology, Japan; 3PRESTO, allows direct imaging of sub-picosecond dynamics on surfaces with Japan Science and Technology Agency, Japan; 4Center for nanometer spatial resolution is described. Quantum Science and Technology under Extreme Conditions, Osaka University, Japan. ABSTRACT Femtosecond transient absorption spectroscopy was carried out for energy transfer in photosynthetic purple bacteria LH2 antenna complex conjugated with artificial fluorescent dyes. Time constants of 3 ps and 18 ps were obtained by global analysis.

08.Tue.C.7 12:15 Contributed Primary Process in Light-Harvesting Complex Studied by Pump-Repump-Probe Spectroscopy Kazuki Sobue1, Kenta Abe1, Shunsuke Sakai2, Mamoru Nango3, Hideki Hashimoto3,4, Masayuki Yoshizawa1; 1Department of Physics, Tohoku University, Japan; 2Department of Life and Materials Engineering, Nagoya Institute of Technology, Japan; 3Department of Physics, Osaka City University, Japan; 4OCARINA, Osaka City University, Japan. ABSTRACT Dark excited states of carotenoid in LH1 complex have been investigated by measuring recovery dynamics following

the repump. The S* state is different from the S1 state but is similar to the T state.

28 TECHNICAL SESSIONS ▶

Room A 14:00-15:45 08.Tue.D Pulse Generation Presider: Katsumi Midorikawa (RIKEN, Japan)

08.Tue.D.1 14:00 Contributed Carrier-envelope phase of single-cycle pulses generated through two-color laser ﬁ lamentation TUESDAY Takao Fuji1, Yutaka Nomura1, Yu-Ting Wang2, Atsushi Yabushita2, Chih Wei Luo2; 1National Institutes of Natural Sciences, Japan; 2Department of Electrophysics, National Chiao Tung University, Taiwan. ABSTRACT Carrier-envelope phase (CEP) control of the pulses from two-color ﬁ lamentation has been investigated. The CEP variation with the relative phase between the two-color pulses is explained with a four-wave mixing model.

08.Tue.D.2 14:15 Contributed Spectral Shaping and Continuous Tuning of Multi-color Carrier-envelope Phase Locked Pulse Atsushi Yabushita1, Chih-Hsien Kao1, Takayoshi Kobayashi2,3; 1Electrophysics, National Chiao Tung University, Taiwan; 2Department of Applied Physics and Chemistry and Institute for Laser Science, University of Electro-Communications, Japan; 3CREST, JST, Japan. ABSTRACT We have demonstrated to generate multi-color CEP-locked beams using the non-collinear optical parametric ampliﬁ er. Spatial ﬁ lter in the spatially dispersed seed light was for arbitrary spectral shaping and parabolic chirp was for tunable double color.

08.Tue.D.3 14:30 Contributed High Gain Frequency domain Optical Parametric Amplifi er (FOPA) for High Contrast Pulses Philippe Lassonde1, Maxime Boivin1, Ladan Arissian2, François Légaré1, Bruno E. Schmidt1,3; 1Institut National de la Recherche Sci., Canada; 2Electrical and Computer Engineering, University of New Mexico, USA; 3few-cycle Inc., Canada. ABSTRACT 800nm, nJ level pulses are amplifi ed >2.000 times in a single 2mm BBO crystal, pumped by picosecond 400nm pulses. Experiments evidence that the picosecond pulse contrast within the pump window remains unchanged upon amplifi cation.

08.Tue.D.4 14:45 Contributed Pushing the NOPA to New Frontiers: Output to below 400 nm, MHz Operation and ps Pump Duration Eberhard Riedle1, Maximilian Bradler1, Peter Baum2, Lamia Kasmi2; 1LS für BioMolekulare Optik, Ludwig-Maximillians- Universität Munchen, Germany; 2LS Krausz, Ludwig-Maximilians-Universität München, Germany. ABSTRACT Two sub-ps MHz range Yb-based lasers are used to pump NOPAs at 343 nm. A SHG driven supercontinuum allows tuning down to 395 nm. For a 1-ps pump, supercontinuum seeding is applicable, the pulses are compressed to the 20-fs regime with a potential for sub-10 fs.

08.Tue.D.5 15:00 Contributed Over 1-mJ intense ultrashort optical-vortex pulse generation with programmable topological-charge control by chirped-pulse ampliﬁ cation Keisaku Yamane1,2, Asami Honda1, Yasunori Toda1,2, Ryuji Morita1,2; 1Hokkaido University, Japan; 2JST CREST, Japan. ABSTRACT We demonstrated the generation of over 1-mJ intense optical-vortex pulses of which topological charges were programmably controlled by computer-generated holograms. The pulse duration was characterized to be 27 fs by two-dimensional spectral shearing interferometry.

08.Tue.D.6 15:15 Contributed Tunable Few-Cycle Mid-IR Pulses towards Single-Cycle Duration by Adiabatic Frequency Conversion Peter R. Krogen1, Haim Suchowski2, Gregory J. Stein1, Franz X. Kärtner1,3, Jeffrey Moses1; 1Department of Electrical Engineering and Computer Science and Research Laboratory of Electronics, Massachusetts Institute of Technology, USA; 2NSF Nanoscale Science and Engineering Center, University of California, USA; 3Center for Free-Electron Laser Science, DESY and University of Hamburg, Germany. ABSTRACT Using adiabatic difference frequency generation, we generate Fourier-limited, few-cycle, tunable 2-4-µm mid-IR pulses at µJ- level, with controllable amplitude and phase by shaping before conversion from the near-IR, paving the way for arbitrary single-cycle mid- IR waveforms. 29 ▶ TECHNICAL SESSIONS

08.Tue.D.7 15:30 Contributed Strong fi eld applications of Gigawatt self-compressed pulses from a Kagome fi ber Tadas Balciunas1, Guangyu Fan1, Stefan Haessler1, Coralie Fourcade-Dutin2, Tobias Witting3, Alexander Voronin4, Alexei Zheltikov4,5, Gerome Frédéric2, Gerhard G. Paulus6, Andrius Baltuska1, Fetah Benabid2; 1Technische Universität Wien, Austria; 2Xlim Research Institute, University of Limoges, France; 3Blackett Laboratory, Imperial College London, United Kingdom; 4M.V. Lomonosov Moscow State University, Russian Federation; 5Department of Physics and Astronomy, Texas A&M University, USA; 6Institute of Optics and Quantum Electronics, Germany. ABSTRACT Nonlinear self-compression of 1.7-um pulses in a gas-fi lled Kagome fi ber down to a single cycle duration and pulse energies up to 100 uJ provides a uniquely simple driver source for high-harmonic generation and above-threshold ionization experiments. TUESDAY

Exhibition Hall 15:45-17:15

08.Tue.P2 Poster Session II

08.Tue.P2.1 Analysis of strong-fi eld enhanced ionization of molecules using Bohmian trajectories Ryohto Sawada1,2, Takeshi Sato2, Kenichi L. Ishikawa1,2; 1Applied physics, Graduate School of Enginieering, The University of Tokyo, Japan; 2Photon Science Center, Graduate School of Engineering, The University of Tokyo, Japan. ABSTRACT We investigate strong-fi eld enhanced ionization of 1D hydrogen molecule using Bohmian trajectories. Contrary to the common belief, we fi nd that the electron ejections both from the down- and up-fi eld atoms are comparably important.

08.Tue.P2.2 Observation of Multiphoton Absorptions in Laser-Assisted Electron Scattering in a Femtosecond Intense Laser Field Kakuta Ishida1, Yuya Morimoto1, Reika Kanya1, Kaoru Yamanouchi1; 1The University of Tokyo, Japan. ABSTRACT High-order multiphoton laser-assisted electron scattering processes induced by collision of electrons and Xe atoms in a femtosecond intense laser ﬁ eld were observed for investigating high-order laser-atom interactions.

08.Tue.P2.3 Electronic pre-determination of ethylene fragmentation dynamics Xinhua Xie1, Stefan Roither1, Erik Lötstedt2, Markus Schöffler1, Daniil Kartashov1, Gerhard G. Paulus3,4, Atsushi Iwasaki2, Andrius Baltuska1, Kaoru Yamanouchi2, Markus Kitzler1; 1Photonics Institute, Vienna University of Technology, Austria; 2Department of Chemistry, School of Science, The University of Tokyo, Japan; 3Institute of Optics and Quantum Electronics, Friedrich-Schiller-University Jena, Germany; 4Helmholtz Institute Jena, Germany. ABSTRACT We demonstrate, using ethylene, that controlling lower-valence ionization and ﬁ eld-driven excitation dynamics with ultrashort, intense laser pulses allows steering fragmentation reactions of polyatomic molecules along a certain pathway towards a speciﬁ c set of fragment ions.

08.Tue.P2.4 Two-Photon Rabi Oscillations of Excited He Atoms in Ultrafast Strong Laser Field Ionization Mizuho Fushitani1,2, Chien-Nam Liu3, Akitaka Matsuda1, Tomoyuki Endo1, Yuto Toida1, Yasumasa Hikosaka2,4, Mitsuru Nagasono2, Tadashi Togashi5, Makina Yabashi2,5, Tetsuya Ishikawa2, Toru Morishita6, Akiyoshi Hishikawa1,2; 1Nagoya University, Japan; 2RIKEN, Japan; 3Fu-Jen Catholic University, Taiwan; 4Niigata University, Japan; 5JASRI, Japan; 6The University of Electro- Communications, Japan. ABSTRACT Intensity dependence of polarized He (21P) atoms in intense NIR laser fields are investigated by single-shot photoelectron spectroscopy, revealing two-photon Rabi oscillations between the initial 1s2p and 1snf (n = 5,6) Rydberg states.

08.Tue.P2.5 Determination of Absolute Cross-Sections of Nonresonant EUV-UV Two-Color Two-Photon Ionization of He Mizuho Fushitani1,2, Yasumasa Hikosaka2,3, Akitaka Matsuda1, Tomoyuki Endo1, Eiji Shigemasa2,4, Mitsuru Nagasono2, Takahiro Sato2, Tadashi Togashi5, Makina Yabashi2,5, Tetsuya Ishikawa2, Akiyoshi Hishikawa1,2; 1Nagoya University, Japan; 2RIKEN, Japan; 3Niigata University, Japan; 4Institute for Molecular Science, Japan; 5JASRI, Japan. 30 TECHNICAL SESSIONS ▶

ABSTRACT Single-shot photoelectron spectroscopy was performed for nonresonant EUV-UV two-color two-photon ionization of He. From data analysis on the shot-by-shot basis, the absolute cross-section was determined to be σ(2)(597nm, 268nm) = 4.1(6)×10−52 cm4 s.

08.Tue.P2.6 Direct comparison of multi-photon and EUV single photon probing of molecular relaxation processes 1 1,2 1 1,3 1 1

Thomas Wolf , Markus Koch , Emily F. Sistrunk , Jakob Grilj , Markus Gühr ; Stanford PULSE Institute, SLAC National TUESDAY Accelerator Laboratory, USA; 2Institute of Experimental Physics, Graz University of Technology, Austria; 3Laboratoire de Spectroscopie Ultrarapide, Ecole Polytechnique Fedrale de Lausanne EPFL, Switzerland. ABSTRACT We present a new setup for time-resolved photoelectron and photoion spectroscopy allowing for single-photon EUV or multi-photon NIR ionization. Comparison of different probe schemes reveals disagreements shedding light on the underlying advantages of different probes.

08.Tue.P2.7 Mirrorless Backward SRS in Free-Space Gas Driven by Filament-Initiated UV Laser Daniil Kartashov5,1, Pavel Malevich1, Faffael Maurer1, Skirmantas Alisauskas1, Marko Marangoni2, Giulio Cerullo2, Alexei Zheltikov3,4, Audrius Pugzlys1, Andrius Baltuska1; 1Photonics Institute Vienna University of Technology, Austria; 2IFN-CNR, Dipartimento di Fisica, Politecnico di Milano, Italy; 3Physics Department, International Laser Center, M.V. Lomonosov Moscow State University, Russian Federation; 4Department of Physics and Astronomy, Texas A&M University, USA; 5Friedrich-Schiller University Jena, Germany. ABSTRACT Stimulated Raman scattering combined with ASE lasing from nitrogen molecules in a femtosecond ﬁ lament is shown to provide a highly directional chemical-bond-sensitive coherent readout in the direction opposite to that of the driver laser beams.

08.Tue.P2.8 Laser-coupled R-matrix calculations for high-harmonic spectroscopy Danilo Simoes Brambila1; 1Max Born Institute, Germany. ABSTRACT We develop R-matrix calculations for systems embedded in a quasi static ﬁ eld. We report the ﬁ eld effects on the Rydberg series of

Helium, and on the tunnel ionization rates of CO2.

08.Tue.P2.9 Laser Induced Rescattering Photoelectron Spectroscopy on Hydrocarbon Molecules Yuta Ito1, Misaki Okunishi1, Chuncheng Wang2, Robert R. Lucchese3, Toru Morishita4, Oleg I. Tolstikhin5, Lars B. Madsen6, Kiyoshi Ueda1; 1Tohoku University, Japan; 2Jilin University, China; 3Texas A&M University, USA; 4University of Electro- Communications, Japan; 5National Research Centre “Kurchatov Institute”, Russian Federation; 6Aarhus University, Denmark.

+ + ABSTRACT We have extracted field-free differential cross sections of electron scattering from C2H4 and C2H6 ions from rescattering photoelectron spectra of C2H4 and C2H6 induced by ultrashort intense infrared laser pulses at 1300 and 1650 nm.

08.Tue.P2.10 Non-adiabatic Effects in Electron Momenta Cornelia Hofmann1, Alexandra S. Landsman1, Claudio Cirelli1, Ursula Keller1; 1Physics Department, ETH Zurich, Switzerland. ABSTRACT In strong-field tunnel ionization of Helium, both adiabatic and fully non-adiabatic theoretical descriptions predict smaller final longitudinal electron momentum distributions than measured experimentally. Semiclassical simulations including an initial longitudinal momentum spread reproduce experimental values.

08.Tue.P2.11 Nonlinear Fourier-transform spectroscopy using ultrabroadband femtosecond pulses for the measurement of photobleaching of ﬂ uorescent proteins Akira Suda1; 1Tokyo University of Science, Japan. ABSTRACT We examine the mechanism of photobleaching of fluorescent proteins using nonlinear Fourier-transform spectroscopy with ultrabroadband femtosecond pulses. Photobleaching of two-photon excited ﬂ uorescent molecules occurs through one-photon excited-state absorption.

08.Tue.P2.12 Vibrational Dynamics in Photoactive Yellow Protein Revealed by Mid-IR Pump / Visible Probe Spectroscopy 31 ▶ TECHNICAL SESSIONS

Ryosuke Nakamura1, Norio Hamada1; 1Osaka University, Japan. ABSTRACT Vibrational dynamics of the chromophore in photoactive yellow protein is studied by mid-IR-pump-visible-probe spectroscopy. So- called ‘ground state intermediate’, which is believed to be a cis isomer, is directly generated by vibrational excitation.

08.Tue.P2.13 Light Harvesting Dynamics in Gloeobacter Rhodopsin (GR) E Siva Subramaniam Iyer1, Itay Gdor1, Tamar Eliash2, Mordechai Sheves2, Sanford Ruhman1; 1Institute of Chemistry, Hebrew University of Jerusalem, Israel; 2Department of Organic Chemistry, Weizmann Institute, Israel. ABSTRACT GR is directly shown by ultrafast pump-probe measurements to bind the carotenoid Salinixanthin, which acts as an efﬁ cient light harvesting antenna. Along with Xanthorhodopsin, This proves light harvesting to be a prevalent strategy in retinal proteins. TUESDAY

08.Tue.P2.14 Ultrafast Relaxation and Photodissociation Dynamics of 1,3-Butadiene Studied by Probing Molecular Orbitals Ayumu Makida1, Takehisa Fujiwara1, Taro Sekikawa1, Yu Harabuchi2, Tetsuya Taketsugu2; 1Applied Physics, Hokkaido University, Japan; 2Chemistry, Hokkaido University, Japan. ABSTRACT Femtosecond relaxation and picosecond photodissociation dynamics of 1,3-butadiene were investigated by time-resolved photoelectron spectroscopy with high harmonics pulses, probing the deeper molecular orbitals which are sensitive to the molecular structure.

08.Tue.P2.15 Ultrafast Time-Domain Raman Study to Visualize Large-Amplitude Distortions in Copper Complexes Satoshi Takeuchi1,2, Munetaka Iwamura3, Tahei Tahara1,2; 1RIKEN, Japan; 2RIKEN Center for Advanced Photonics, Japan; 3University of Toyama, Japan. ABSTRACT Time-resolved impulsive-Raman with narrowband photoexcitation was utilized to study structural dynamics of bis-diimine copper complex in solution. A copper-ligand symmetric stretch band showed up with frequency oscillation, demonstrating its anharmonic coupling with large-amplitude distortional motions.

08.Tue.P2.16 Control of Chemical Bond Break with both Electronic and Nuclear Dynamics Xinhua Xie1, Erik Lötstedt2, Stefan Roither1, Markus Schöfﬂ er1, Daniil Kartashov1, Kaoru Yamanouchi3, Katsumi Midorikawa2, Andrius Baltuška1, Markus Kitzler1; 1Photonics Institute, Vienna University of Technology, Austria; 2Laser Technology Laboratory, RIKEN, Japan; 3Department of Chemistry, The University of Tokyo, Japan. ABSTRACT We experimentally demonstrated control of chemical bond break of ethylene in intense laser ﬁ elds with employing both electronic dynamics and nuclear vibrational dynamics.

08.Tue.P2.17 Observing the Elusive Double-Peak Structure in R-dependent Tunneling Ionization Rate of Hydrogen Molecular Ion Igor Litvinyuk1, Han Xu1, Tian-Yu Xu3, Feng He3, Dave Kielpinski1,2, Robert Sang1,2; 1Centre for Quantum Dynamics, Griffith University, Australia; 2ARC Centre for Coherent X-ray Science, Grifﬁ th University, Australia; 3Department of Physics and Astronomy, SJTU, China.

ABSTRACT We performed pump-probe experiment on H2 using intense few-cycle laser pulses and Reaction Microscope detection apparatus. We observe the theoretically predicted double-peak structure in R-dependent tunneling ionization rate for the ﬁ rst time experimentally.

08.Tue.P2.18 Time-resolved Coulomb Explosion Imaging of Ultrafast Fragmentation of

CS2 in Highly Charged States Akitaka Matsuda1, Eiji J. Takahashi2, Akiyoshi Hishikawa1; 1Department of Chemistry, Graduate School of Science, Nagoya University, Japan; 2Attosecond Science Research Team, RIKEN Center for Advanced Photonics, Japan.

ABSTRACT Time-resolved Coulomb explosion imaging of CS2 in few-cycle intense laser ﬁ elds revealed that the ultrafast fragmentation dynamics

of CS2 in highly charged states proceed in a different timescale depending on the charge state.

32 TECHNICAL SESSIONS ▶

08.Tue.P2.19

Ionization of Aligned O2 by Intense Laser Pulse Kotaro Sonoda1, Hirokazu Hasegawa1, Takahiro Sato2, Atsushi Iwasaki2, Kaoru Yamanouchi2; 1Integrated Sciences, University of Tokyo, Japan; 2Chemistry, University of Tokyo, Japan.

+ 2+ ABSTRACT Intense ﬁ eld ionization of aligned O2 is investigated by a pump-probe method. The different behavior of O2 and O2 yields against a pump-probe delay is ascribed to the angular dependence of the ionization probability. TUESDAY 08.Tue.P2.20 Multidimensional Photochemistry Models: Application to Aminobenzonitrile and Benzopyran Aurelie Perveaux1,3, Pedro Javier Castro Pelaez2, Mar Reguero2, Hans-Dieter Meyer4, Fabien Gatti3, David Lauvergnat1, Benjamin Lasorne3; 1Chimie, LCP, France; 2Quimica ﬁ sica i inorganica, Pl. Imperial Tarraco, Spain; 3Chimie, CTMM, France; 4Theoretische Chemie, Physikalisch-Chemische Institut, Germany. ABSTRACT To understand the photoreactivity of aminobenzonitrile and benzopyran, their electronic structures and the potential energy landscapes were analyzed at the CASSCF level and models were developed to perform quantum dynamics calculations

08.Tue.P2.21 Femtosecond Pump - Probe Spectroscopy Reveals the Photo-excited State and Charge Transfer of a Photocatalytic Metal-Organic Framework Monique van der Veen1,2, Kamila Mazur2, Maxim Nasalevich1, Martijn Hurkmans1, Jorge Gascon1, Freek Kapteijn1, Arjan Houtepen1, Ferdinand Grozema1, Mischa Bonn2, Johannes Hunger2; 1Delft University of Technology, Netherlands; 2Max-Planck Institute for Polymer Research, Germany.

ABSTRACT With femtosecond pump-probe spectroscopy we found for photocatalytically active NH2-MIL-125 that after photo-excitation the hole resides on -NH2. Charge transfer from the MOF to an occluded molecule capable to shuttle single charges to a reaction centre is extremely fast (< 200 fs) while charge recombination only occurs on the ns-µs time scale.

08.Tue.P2.22 Coherent Control of the Photodissociation of Triiodide in Solution Reveals New Pathways Rui Xian1, Valentyn Prokhorenko1, Ryan L. Field2, Dwayne Miller1,2; 1Max Planck Institute (MPSD), Germany; 2Chemistry and Physics, University of Toronto, Canada. ABSTRACT We demonstrate control of the photodissociation of triiodide, solvated in ethanol, via phase-shaped UV pulses. The second-order chirp dependence of the diiodide yield hints at additional pathways involving higher-lying potential energy surfaces.

08.Tue.P2.23 Solvent Environment Revealed by Positively Chirped Pulses Arkaprabha Konar1, Vadim V. Lozovoy1, Marcos Dantus1,2; 1Michigan State University, USA; 2Physics and Astronomy, Michigan State University, USA. ABSTRACT We compare the ﬂ uorescence yield for laser dyes as a function of linear chirp. Negatively chirped pulses are insensitive to solvent viscosity while positively chirped pulses are found to be uniquely sensitive probes of solvent viscosity.

08.Tue.P2.24 Interpreting Coherence Beats in Numerically Exact Simulations of 2D Spectra Daniele Monahan1, Lukas Whaley-Mayda1, Akihito Ishizaki2, Graham R. Fleming1; 1Chemistry, University of California, Berkeley, USA; 2Institue for Molecular Science, Natural Institute of Natural Sciences, Japan. ABSTRACT Coherence beats are simulated in a numerically exact hierarchy method treatment of an electronic heterodimer coupled to a vibration and bath. We vary coupling parameters to analyze the lifetimes and contributions from different Liouville pathways.

08.Tue.P2.25

Long-Lived Neutral H2 in Hydrogen Migration within Hydrocarbon Dication Katsunori Nakai1, Kaoru Yamanouchi1; 1Department of Chemistry, School of Science, The University of Tokyo, Japan.

2+ 2+ ABSTRACT First principles molecular dynamics calculations of energized CH3NH2 and CH3CH3 show that a long-lived neutral H2 moiety is + formed within a doubly charged parent ion,leading eventually to the formation of H3 .

33 ▶ TECHNICAL SESSIONS

08.Tue.P2.26 Time-Resolved Impulsive Raman Study of Excited State Structures of Green Fluorescent Protein Tomotsumi Fujisawa1, Hikaru Kuramochi1, Satoshi Takeuchi1,2, Tahei Tahara1,2; 1Molecular Spectroscopy Lab., RIKEN, Japan; 2Ultrafast Spectroscopy Research Team, RIKEN Center for Advanced Photonics, Japan. ABSTRACT Structural dynamics of green ﬂ uorescent protein was studied by femtosecond time-resolved impulsive Raman spectroscopy. The excited-state vibrational spectra of the protein with three different chromophore forms were obtained, revealing their structural differences and excited-state deprotonation.

08.Tue.P2.27

TUESDAY Hydrogen Bond Dynamics in Alcohols Studied by 2D IR Spectroscopy Keisuke Shinokita1, Ana Cunha1, Thomas Jansen1, Maxim S. Pshenichnikov1; 1Zernike Institute for Advanced Materials, University of Groningen, Netherlands. ABSTRACT Ultrafast hydrogen-bond dynamics in alcohols are studied with 2D IR spectroscopy and combined molecular dynamics - quantum mechanical simulations on the OH stretching mode. Timescales of ~200 fs and 1 ps are attributed to hydrogen-bond ﬂ uctuations and hydrogen- bond exchange dynamics, respectively.

08.Tue.P2.28 Excited-state dynamics of catalytically active transition metal complexes studied by transient photofragmentation in gas phase and transient absorption in solution Dimitri Imanbaew1, Yevgeniy Nosenko1, Katharina Chevalier2, Fabian Rupp2, Christian Kerner1, Frank Breher3, Werner Thiel1, Christoph Riehn1, Rolf Diller2; 1Chemistry and OPTIMAS, TU Kaiserslautern, Germany; 2Physics, TU Kaiserslautern, Germany; 3Inorganic Chemistry, Karlsruhe Institute of Technology (KIT), Germany. ABSTRACT Femtosecond photofragmentation (gas phase) and transient absorption (solution) revealed ultrafast electronic coupling (0.1-3ps) and

energy transfer (7-12 ps) in a Ru(II)-complex and ultrafast formation (~0.4ps) of a long-lived triplet state in a Pd3-complex.

08.Tue.P2.29 Femtosecond transient absorption measurement of energy and charge transfers in donor-acceptor liquid crystalline dyad and triad Jae Heun Woo5, Kwang Jin Lee1, Leszek Mazur2,3, Eun Sun Kim1, Yiming Xiao3, Fabrice Mathevet3, André-Jean Attias3, Jeong Weon Wu1, Jean-Charles Ribierre1,4; 1Department of Physics & CNRS-Ewha International Research Center, Ewha Womans University, Republic of Korea; 2Laboratory of Polymer Chemistry, University Pierre et Marie Curie, France; 3Institute of Physical and Theoretical Chemistry, Wroclaw University of Technology, Poland; 4Center for Organic Photonics and Electronics Research, Kyushu University, Japan; 5Center for Length, Division of Physical Metrology, Korea Research Institute of Standards and Science (KRISS), Republic of Korea. ABSTRACT We investigated the energy transfer and charge transfer processes in dyad and triad based on triphenylene (donor) and perylene (acceptor) units by femtosecond transient absorption spectroscopy. Our results demonstrate that energy transfer from triphenylene to perylene occurs in solution and charge transfer is observed in thin ﬁ lms.

08.Tue.P2.31 Snapshots of Dirac Fermions near the Dirac Point in Topological Insulators Tien-Tien Yeh1, Chih Wei Luo1, Harn-Jiunn Wang1, Shin-An Ku1, Hsueh-Ju Chen1, Jiunn-Yuan Lin2, Kaung-Hsiung Wu1, Jenh- Yih Juang1, Ben-Li Young1, Takayoshi Kobayashi3, Cheng-Maw Cheng4, Ching Hung Chen4, Ku-Ding Tsuei4, Fang-Cheng Chou5; 1Electrophysics, National Chiao Tung University, Taiwan; 2Physics, National Chiao Tung University, Taiwan; 3Engineering Science, University of Electro-Communications, Japan; 4National Synchrotron Radiation Research Center, Taiwan; 5Center for Condensed Matter Sciences, National Taiwan University, Taiwan. ABSTRACT We utilized a ultrafast optical pump mid-infrared probe to explore the dynamics of Dirac fermions near the Dirac point in topological insulator. The femtosecond snapshots of the relaxation process were revealed by the ultrafast optics.

08.Tue.P2.32 [Canceled]

34 TECHNICAL SESSIONS ▶

08.Tue.P2.33

Beating of Terahertz Pulse Induced Spin Precession in ErFeO3 Keita Yamaguchi1, Takayuki Kurihara1, Hiroshi Watanabe1, Makoto Nakajima2, Takeo Kato1, Tohru Suemoto1; 1Institute for Solid State Physics, The University of Tokyo, Japan; 2Graduate School of Science, Chiba University, Japan.

ABSTRACT Terahertz pulse induced spin precession in ErFeO3 was observed via the Faraday rotation of the visible probe pulse. Unreported splitting of the magnetic resonance was discovered and mechanism explaining this splitting is proposed. TUESDAY 08.Tue.P2.34 Ultrafast charge photogeneration and dynamics in semiconducting carbon nanotubes Giancarlo Soavi1, Francesco Scotognella1, Daniele Viola1, Timo Hefner2, Tobias Hertel2, Guglielmo Lanzani3, Giulio Cerullo1; 1IFN-CNR Dipartimento di Fisica, Politecnico di Milano, Italy; 2Department of Chemistry and Pharmacy, University of Wuerzburg, Germany; 3Center for Nano Science and Technology@PoliMi, Istituto Italiano di Tecnologia, Italy. ABSTRACT We show that charge-carriers are instantaneously photogenerated in semiconducting carbon nanotubes by identifying their spectral signature in transient absorption. We exploit carbon nanotubes as ideal systems for the study of charge-carriers dynamics in one dimension.

08.Tue.P2.35

Observation of the Photoinduced Phase Transition in Me4P[Pt(dmit)2]2 by Femtosecond Electron Diffraction Stuart Hayes1, Tadahiko Ishikawa2, Sercan Keskin1, Masaki Hada2,3, Alexander Marx1, Gaston Corthey1, Kostyantyn Pichugin1, Mitsushiro Nomura4, Reizo Kato4, Ken Onda2,3, Yoichi Okimoto2, Shin-ya Koshihara2,5, R. J. Dwayne Miller1; 1Max-Planck Institute (MPSD), Germany; 2Tokyo Institute of technology, Japan; 3JST-PRESTO, Japan; 4RIKEN, Japan; 5JST-CREST, Japan. ABSTRACT Femtosecond electron diffraction has been used to probe the photoinduced phase transition in the strongly-correlated system,

Me4P[Pt(dmit)2]2, revealing molecular motions involved in this process and breaking new ground in terms of chemical complexity.

08.Tue.P2.36 Ultrafast Magnetostriction of Antiferromagnetic Holmium studied by Femtosecond X-Ray Diffraction Daniel Schick1, Alexander von Reppert1, Matthias Rössle1, Matias Bargheer1,2; 1Institut für Physik, Universität Potsdam, Germany; 2Helmholtz-Zentrum Berlin für Materialien und Energie GmbH, Germany. ABSTRACT We present time-resolved X-ray diffraction data on antiferromagnetic Holmium thin ﬁ lms after direct femtosecond laser excitation. The strong magnetostriction in Holmium allows to correlate the observed ultrafast lattice dynamics to the antiferromagnetic helical spin structure.

08.Tue.P2.37 II Ultrafast Dynamics of Single Crystal [Fe (bpy)3](PF6)2 Ryan Field1,2, Lai Chung Liu1,2, Cheng Lu1, Wojciech Gawelda3, Yifeng Jiang1,2, Dwayne Miller1,2; 1University of Toronto, Canada; 2Max Planck Institute for Structural Dynamics, Germany; 3European XFEL, Germany. ABSTRACT Transient absorption spectroscopy is used to characterize the ultrafast spin-transfer process in single crystal iron(II)- tris(bipyridine)-bis(hexaﬂ uorophosphate). Preliminary data analysis shows evidence of the formation of a high spin state and oscillatory signals on multiple time scales.

08.Tue.P2.38

Single-shot Real-time Observation of Ultrafast Amorphization in Ge2Sb2Te 5 Thin Film Wataru Oba1, Ikufumi Katayama1, Yasuo Minami1, Toshiharu Saiki2, Jun Takeda1; 1Yokohama National University, Japan; 2Graduate School of Science and Technology, Keio University, Japan.

ABSTRACT Ultrafast dynamics of photo-induced amorphization in Ge2Sb2Te 5 thin ﬁ lm has been studied using broadband single-shot real-time pump-probe imaging spectroscopy. We successfully observed the transient absorption changes accompanied with the ultrafast amorphization with a single-shot detection.

08.Tue.P2.39 Femtosecond demagnetization of ferromagnetic metal: cooperative precession of delocalized spins Jaedong Lee1, Won Seok Yun1,2; 1Dept. Emereging Materials Science, DGIST, Republic of Korea; 2Center for X-ray Optics, LBNL, USA. 35 ▶ TECHNICAL SESSIONS

ABSTRACT A microscopic model of coherent Elliot-Yafet phonon inducing the delocalized spin precession is proposed to drive a cooperative femtosecond quenching of the magnetization in ferrromagnetic metal, beyond the phenomenological temperature model.

08.Tue.P2.40 Accessing Energy-Dependent Photoemission Delays in Solids Matteo Lucchini1, Luca Castiglioni2, Reto Locher1, Michael Greif2, Lukas Gallmann1,3, Jürg Osterwalder2, Matthias Hengsberger2, Ursula Keller1; 1ETH Zurich, Switzerland; 2University of Zurich, Switzerland; 3University of Bern, Switzerland. ABSTRACT Our new detection scheme combines the RABBITT technique in solids with simultaneous measurements in a reference argon target. The experiment resolved attosecond delays in the photoemission from noble metal surfaces beyond simple ballistic transport. TUESDAY 08.Tue.P2.41 10 fs dynamics of photoinduced magnetic transition in

double-layered charge ordering in LuFe2O4 under interlayer excitation Yuto Sagae1, Kentaro Yamada1, Takahiro Ishikawa1, Keisuke Itoh1, Hirotake Itoh1,2, Takahiko Sasaki3, Tomoko Nagata4, Jun Kano4, Takashi Kambe4, Sumio Ishihara1, Naoshi Ikeda4, Shinichiro Iwai1,2; 1Physics, Tohoku University, Japan; 2CREST, JST, Japan; 3Institute for Materials Research, Tohoku University, Japan; 4Physics, Okayama University, Japan.

ABSTRACT Photoinduced ferrimagnetic to antiferromagnetic transition was investigated in double layered Fe oxide LuFe2O4 by 12fs infrared pulse. Inter-layer charge imbalance successively induce the changes of charge/magnetic structures interacting with several phonons through the exchange interaction.

08.Tue.P2.42 Terahertz Induced Electromigration Andrew C. Strikwerda1, Maksim Zalkovskij1, Krzysztof Iwaszczuk1, Peter Uhd Jepsen1; 1Danmarks Tekniske Universitet, Denmark. ABSTRACT We report the fi rst observation of THz-fi eld-induced electromigration in sub-wavelength metallic gap structures after exposure to intense single-cycle, sub-picosecond electric fi eld transients of amplitude up to 400 kV/cm.

08.Tue.P2.43 Ultrafast Lattice Dynamics of Phase-change Materials Monitored by a Pump-pump-probe Technique Muneaki Hase1, Paul Fons2, Kirill Mitrofanov2, Alexander Kolobov2, Junji Tominaga2; 1Institute of Applied Physics, University of Tsukuba, Japan; 2Nanoelectronics Research Institute, National Institute of Advanced Industrial Science and Technology, Japan.

ABSTRACT We explore ultrafast structural transformation in the Ge2Te 2/Sb2Te 3 superlattice, using pump-pump-probe spectroscopy. The coherent phonon spectra exhibit complex structural dynamics upon photo-excitation, being described as the mixing of two different Ge bonding conﬁ gurations.

08.Tue.P2.44 Sagnac Interferometer for Two-Dimensional Femtosecond Spectroscopy in the Pump-Probe Geometry Samuel Park1, Trevor Courtney1, Dmitry Baranov1, Byungmoon Cho1, David Jonas1; 1Department of Chemistry and Biochemistry, University of Colorado at Boulder, USA. ABSTRACT An intrinsically phase-stable Sagnac interferometer is introduced for enhanced sensitivity detection in partially collinear two- dimensional spectroscopy in the short-wave IR. The sensitivity and phase accuracy of the apparatus are demonstrated on the dye IR-26.

08.Tue.P2.45 Ultrafast Non-Thermal Response of Plasmonic Resonance in Gold Nanoantennas Giancarlo Soavi1, Giuseppe Della Valle1, Paolo Biagioni1, Andrea Cattoni2, Stefano Longhi1, Giulio Cerullo1, Daniele Brida3; 1Politecnico di Milano, Italy; 2Laboratoire de Photonique et de Nanostructures, France; 3University of Konstanz, Germany. ABSTRACT Ultrafast thermalization of electrons in metal nanostructures is studied by means of pump-probe spectroscopy. We track in real-time the plasmon resonsance evolution, providing a tool for understanding and controlling gold nanoantennas non-linear optical response.

08.Tue.P2.46 Ultrafast Terahertz Response of Lithium Niobate in the Nonperturbative Regime Carmine Somma1, Klaus Reimann1, Michael Woerner1, Thomas Elsaesser1, Christos Flytzanis2; 1Max-Born-Institut, 36 TECHNICAL SESSIONS ▶

Germany; 2École Normale Supérieure, France.

ABSTRACT The response of a LiNbO3 crystal to THz pulses in the nonperturbative regime is studied by two-dimensional spectroscopy. Phase- resolved detection allows for separating the THz bulk photovoltaic effect from other nonlinear contributions.

08.Tue.P2.47 Resonant Optical Kerr Response with Ultrashort Decay Time by

Nonlocal Wave Coupling of Light and Excitons TUESDAY Masayoshi Ichimiya1, Takayuki Umakoshi1, Hiroyuki Murata1, Takashi Kinoshita2, Hajime Ishihara2, Masaaki Ashida1; 1Graduate School of Engineering Science, Osaka University, Japan; 2Graduate School of Engineering, Osaka Prefecture University, Japan. ABSTRACT Resonant optical Kerr effects have been investigated in high-quality CuCl thin films. The peculiar spectral feature and ultrafast response below 200 fs due to a long-range coherent coupling between light and multinode-type excitons are observed.

08.Tue.P2.48 Controlling Dirac Carrier Dynamics in Graphene via Phonon Pumping Isabella Gierz1, Matteo Mitrano1, Hubertus Bromberger1, Andrea Cavalleri1, Cephise Cacho2, Richard Chapman2, Emma Springate2, Stefan Link3, Ulrich Starke3; 1Max Planck Institute for the Structure and Dynamics of Matter, Germany; 2Central Laser Facility, STFC Rutherford Appleton Laboratory, United Kingdom; 3Max Planck Institute for Solid State Research, Germany.

ABSTRACT Using time- and angle-resolved photoemission spectroscopy, we ﬁ nd that resonant excitation of the in-plane E1u lattice vibration in epitaxial bilayer graphene leads to a decrease of the relaxation time associated with electron - optical phonon coupling.

08.Tue.P2.49 Infrared double optical gating for generating submicrojoule isolated attosecond pulses Eiji J. Takahashi1, Pengfei Lan1, Katsumi Midorikawa1; 1RIKEN Center for Advanced Photonics, Japan. ABSTRACT We experimentally demonstrate an infrared two-color polarization gating scheme for generating an intense isolated attosecond pulse using the multicycle laser. The obtained submicrojoule continuum harmonic spectrum supports the generation of a pulse duration of sub-500 as.

08.Tue.P2.50 Ultrafast 2 µm Laser Oscillators Based on Thulium-Doped ZBLAN Fibers Yutaka Nomura1, Masatoshi Nishio2, Sakae Kawato2,3, Takao Fuji1; 1Institute for Molecular Science, Japan; 2Graduate School of Engineering, University of Fukui, Japan; 3Research and Education Program for Life Science, University of Fukui, Japan. ABSTRACT Mode-locked fi ber laser oscillators are demonstrated by using thulium-doped ZBLAN fi bers. Thanks to very low dispersion of ZBLAN glass fi bers, pulses as short as 45 fs are generated at 1900 nm.

08.Tue.P2.51 Wavefront Analysis of High-Efﬁ ciency, Large-Scale, Thin Transmission Gratings Chun Zhou1,4, Takashi Seki2, Tsuyoshi Kitamura2, Yoshiyuki Kuramoto2, Takashi Sukegawa2, Nobuhisa Ishii3, Teruto Kanai3, Jiro Itatani3, Yohei Kobayashi3, Shuntaro Watanabe1,4; 1Tokyo University of Science, Japan; 2Corporate R&D Headquarters, CANON Inc., Japan; 3Institute for Solid State Physics, University of Tokyo, Japan; 4CREST, Japan Science and Technology Agency (JST), Japan. ABSTRACT Large-scale transmission gratings with groove densities of 1250 and 1740 lines/mm have been developed with diffraction efﬁ ciencies above 95%. The minimized bending of the grating results in a negligible wavefront distortion of a pulse compressor.

08.Tue.P2.52 In-Situ Measurement of Intensity-Dependent Carrier-Envelope Phase Changes in Hollow Fiber Compression Fabian Lücking1, Andrea Trabattoni2, Sunilkumar Anumula2, Giuseppe Sansone2, Francesca Calegari2, Mauro Nisoli2, Thomas Oksenhendler3, Gabriel Tempea1; 1Femtolasers Produktions GmbH, Austria; 2Politecnico di Milano, Department of Physics, Institute of Photonics and Nanotechnologies,CNR-IFN, Italy; 3Fastlite, France. ABSTRACT We report on a single-shot, in-situ interferometric method for measuring intensity-dependent phase changes in laser pulse propagation. With this method, the impact of hollow ﬁ ber compressors on phase stability was characterized.

37 ▶ TECHNICAL SESSIONS

08.Tue.P2.53 Measurement and Characterization of sub-5 fs Broadband UV Pulses in the 230-350 nm Range Valentyn Prokhorenko1, Samansa Maneshi1, R. J. Dwayne Miller1; 1Max Planck Institute for Structure and Dynamics of Matter, Germany. ABSTRACT We report a new design of all-reflective 3rd-order frequency resolved optical gating setup (FROG) for measurement and characterization of ultrashort UV-pulses in the 230-350 nm range and tested it using 7.3 fs pulses generated in the 250-300 nm range. This setup allows also heterodyne detection which signiﬁ cantly increases its sensitivity.

08.Tue.P2.54

TUESDAY Femtosecond Pulses in 375 nm - 405 nm Region by Chirped Sum Frequency Prem B. Bisht1, Akbar S. Ali1; 1Indian Institute of Technology, Madras, India. ABSTRACT Tunable femtosecond pulses have been obtained from nJ pulse energies of the oscillator by sum frequency between the fundamental and the chirped pulse. The pulse has been characterized by the same set up.

08.Tue.P2.55 Two Novel Schemes for Photon-Number Squeezed Pulse Generation in Ultrafast Nonlinear Fiber Optics Aruto Hosaka1, Shota Sawai1, Kenichi Hirosawa1, Fumihiko Kannari1; 1Keio University, Japan. ABSTRACT We experimentally prove two novel techniques which solve issues in photon-number squeezed pulse generation: one is with Er- doped ﬁ ber laser source, and the other is with a normal dispersion ﬁ ber at 800 nm.

08.Tue.P2.56 Ultra-Broadband Mid-IR OPCPA Schemes Enabled By Quasi-Phase-Matching Christopher R. Phillips1,2, Benedikt W. Mayer1, Lukas Gallmann1,3, Martin M. Fejer2, Ursula Keller1; 1ETH Zurich, Switzerland; 2Stanford University, USA; 3University of Bern, Switzerland.

ABSTRACT We present mid-IR OPCPA system conﬁ gurations producing sub-four-cycle pulses, based on PPMgO:LiNbO3. We demonstrate an all-collinear system via APPLN, and a hybrid system with a noncollinear PPLN power ampliﬁ er. Combining these techniques could offer octave- spanning-OPCPA.

08.Tue.P2.57 Solitonic Regime of Mid-infrared Filamentation at Highly Overcritical Power in Transparent Solids Daniil Kartashov5, Pavel Malevich1, Skirmantas Alisauskas1, Audrius Pugzlys1, Alexander Voronin2, Alexei Zheltikov2,3, Daniele Faccio4, Andrius Baltuska1; 1Photonics Institute Vienna University of Technology, Austria; 2Physics Department, International Laser Center, M.V. Lomonosov Moscow State University, Russian Federation; 3Department of Physics and Astronomy, Texas A&M University, USA; 4Institute of Photonics and Quantum Sciences, Heriot-Watt University Edinburgh, United Kingdom; 5Friedrich- Schiller University Jena, Germany. ABSTRACT Filamentation of femtosecond pulses in transparent solids with anomalous group-velocity dispersion is investigated for a broad range

of the peak powers. Solitonic self-compression of multi-millijoule mid-IR pulses is achieved using a 1.5-mm-thick CaF2 plate.

08.Tue.P2.58 Generation and characterization of microJoule-level 10 fs UV pulses Rocio Borrego Varillas1, Alessia Candeo1, Sandro De Silvestri1, Giulio Cerullo1, Cristian Manzoni1; 1IFN, CNR - Politecnico di Milano, Italy. ABSTRACT We demonstrate microJ-level 10-fs pulses in the 315-380 nm spectral range generated by broadband sum-frequency generation. The pulses are characterized using 2D spectral shearing interferometry based on difference-frequency with a visible NOPA.

08.Tue.P2.59 Generating Efﬁ cient Femtosecond Mid-infrared Pulse by Single Near-infrared Pump Wavelength in Bulk Nonlinear Crystal Without Phase-matching Binbin Zhou1, Hairun Guo1, Morten Bache1; 1Danmarks Tekniske Universitet, Denmark. ABSTRACT We experimentally demonstrate efﬁ cient mid-infrared pulse generation by dispersive wave radiation in bulk lithium niobate crystal. Femtosecond mid-infrared pulses centering from 2.8-2.92 µm are generated using the single pump wavelengths from 1.25-1.45 µm.

38 TECHNICAL SESSIONS ▶

08.Tue.P2.60 Spatiotemporal Dynamics of Femtosecond Pulses Shaped by Diffractive Optical Elements (DOEs) Rocio Borrego Varillas1,2, Benjamin Alonso1, Jorge Perez Vizcaino2, Isabel Gallardo Gonzalez3, Glaldys Minguez-Vega2, Omel Mendoza-Yero2, Jesus Lancis2, Andrew Forbes4, Iñigo Sola1; 1Universidad de Salamanca, Saint Barthelemy; 2Universitat Jaume I, Spain; 3Centro de Làseres Pulsados, Spain; 4CSIR National Laser Center, South Africa. ABSTRACT We present a complete experimental characterization and simulation of the spatiotemporal and spatio-spectral effects taking place when a femtosecond pulse is shaped by a diffractive optical element. TUESDAY

Room A 17:15-19:00 08.Tue.E Singlet Imaging and Charge Transfer Presider: Gregory Scholes (University of Toronto, Canada)

08.Tue.E.1 17:15 Contributed Ultrafast charge generation, high and balanced charge carrier mobilities in organo halide perovskite solar cell Carlito S. Ponseca1, Mohamed Abdellah1, Kaibo Zheng1, Arkady Yartsev1, Tobjorn Pascher1, Tobias Harlang1, Pavel Chabera1, Tonu Pullerits1, Andrey Stepanov2, Jean-Pierre Wolf2, Villy Sundstrom1; 1Chemical Physics, Lunds Universitet, Sweden; 2GAP- Biophotonics, University of Geneva, Switzerland. ABSTRACT Using terahertz and transient absorption spectroscopy, carrier dynamics in organo halide perovskite solar cell is probed. Charge generation is <100 fs, followed by 2 ps charge formation with balanced electron hole mobility of 20 cm2 V -1s -1.

08.Tue.E.2 17:30 Contributed Charge Transfer Dynamics between Colloidal Nanocrystals and Graphene Holger Lange1, Christian Strelow1, Robert A. Barton2, Octavi E. Semonin2, Erik Busby3, Matthew Sfeir3, Tony F. Heinz2; 1Universitaet Hamburg, Germany; 2Columbia University, USA; 3Brookhaven National Laboratory, USA. ABSTRACT We apply time-resolved photoluminescence and ultrafast transient absorption spectroscopy to investigate the electron transfer between PbS nanocrystals and graphene. We ﬁ nd sub-ns decay times and we ﬁ nd strong evidence for a major contribution of charge transfer.

08.Tue.E.3 17:45 Contributed Ultrafast Optical Control of Charge Dynamics in Organic and Hybrid Electronic Nanodevices Artem Bakulin1, Robert Lovrincic5, Simon Gelinas2, Akshay Rao2, Yu Xi3, Oleg Selig1, Zhuoying Chen4, Richard Friend2, Huib Bakker1, David Cahen3; 1FOM Institute AMOLF, Netherlands; 2University of Cambridge, United Kingdom; 3Weizmann Institute of Science, Israel; 4ESPCI/CNRS/UPMC UMR, France; 5InnovationLab, Germany. ABSTRACT Using ultrafast visible/IR pulse-sequence spectroscopy combined with electric current detection, we engage vibronic and charge- delocalization phenomena to control the performance of optoelectronic devices base on organic semiconductors, colloidal quantum dots and conductive oxides.

08.Tue.E.4 18:00 Contributed Ultrafast Spectroscopy Reveals Bulk Heterojunction Morphology Maxim S. Pshenichnikov1, Almis Serbenta1, Paul van Loosdrecht1; 1Rijksuniversiteit Groningen, Netherlands. ABSTRACT We propose a new technique to probe the nanosized morphology in polymer-fullerene bulk heterojunctions by ultrafast spectroscopy. The method reveals the size of fullerene clusters in an all-optical way and is applicable “on-the-ﬂ y” to functional photovoltaic devices.

08.Tue.E.5 18:15 Contributed Coherent phonon dynamics in singlet fi ssion of rubrene single crystal Kiyoshi Miyata1, Shunsuke Tanaka1, Toshiki Sugimoto1, Kazuya Watanabe1, Takafumi Uemura2, Jun Takeya2, Yoshiyasu Matsumoto1; 1Chemistry, Kyoto University, Japan; 2Fronteir Science, The Universty of Tokyo, Japan. ABSTRACT We observed wavepacket motions in singlet fi ssion of rubrene single crystal at 35 K. A coherent phonon shows a transient frequency shift, indicating that a transition from S1 to an intermediate state of the fi ssion occurs within 2 ps.

39 ▶ TECHNICAL SESSIONS

08.Tue.E.6 18:30 Contributed Acceleration of Ultrafast Singlet Fission in Aza-derivative of TIPS-Pentacene Tiago Buckup1, Julia Herz1, Marcus Motzkus1; 1Phyisikalisch-Chemisches Institut, Heidelberg University, Germany. ABSTRACT We unveil a new general channel for formation of triplet states via singlet ﬁ ssion in TIPS-pentacene derivatives by probing sub 100 fs dynamics in the near infrared spectral region with transient absorption.

08.Tue.E.7 18:45 Contributed Ultrafast Electron and Hole Dynamics in Novel Conjugated Star-Shaped Molecules Oleg V. Kozlov1,2, Yuriy N. Luponosov3, Sergei A. Ponomarenko3, Dmitry Paraschuk2, Nina Kausch-Busies4, Maxim S.

TUESDAY Pshenichnikov1; 1Zernike Institute for Advanced Materials, University of Groningen, Netherlands; 2International Laser Center and Faculty of Physics, Moscow State University, Russian Federation; 3Institute of Synthetic Polymeric Materials of the Russian Academy of Science, Russian Federation; 4Heraeus Precious Metals GmbH & Co. KG, Conductive Polymers Division, Germany. ABSTRACT Charge dynamics in organic photovoltaic blends based on novel star-shaped molecules are studied by ultrafast visible-IR spectroscopy. Pathways of intra- and intermolecular electron and hole transfer and their recombination are identiﬁ ed and discussed.

40 TECHNICAL SESSIONS ▶

Wednesday, July 9

Room A 08:30-10:15 09.Wed.A 2D Spectroscopy Presider: Steven Cundiff (University of Colorado at Boulder JILA, United States)

09.Wed.A.1 08:30 Invited Ultrabroadband two-dimensional spectroscopy by a birefringent delay line Julien Rehault1, Aurelio Oriana1, Margherita Maiuri1, Daniele Brida2, Dario Polli1, Cristian Manzoni1, Giulio Cerullo1; 1Physics, Politecnico di Milano, Italy; 2Physics, University of Konstanz, Germany. WEDNESDAY ABSTRACT We introduce a passive birefringent delay line for the generation of collinear, interferometrically locked ultrashort pulse pairs. Their delay is controlled with attosecond precision and stability <λ/360, enabling two-dimensional electronic spectroscopy from UV to infrared.

09.Wed.A.2 09:00 Contributed Multidimensional spectroscopy with entangled light; A novel pulse scanning protocol Konstantin E. Dorfman1, Frank Schlawin1,2, Shaul Mukamel1; 1Chemistry, University of California, USA; 2Institute of Physics, Albert-Ludwigs University of Freiburg, Germany. ABSTRACT Quantum light can induce correlations in photo excited molecules and probe them with unusual spectral and temporal resolution. A new non-time-ordered pulse delay scanning protocol in multidimensional signals reveals resonances not accessible by standard techniques.

09.Wed.A.3 09:15 Contributed Two-Dimensional Fourier Transform Infrared-Visible and Infrared-Raman Spectroscopies Trevor L. Courtney1, Zachary W. Fox1, Karla Slenkamp1, Michael Lynch1, Munira Khalil1; 1Chemistry, University of Washington, USA. ABSTRACT Femtosecond nonlinear spectroscopies using new IR and visible pulse sequences are demonstrated, including 2D IR-visible spectroscopy to study vibrational-electronic couplings and 2D IR-Raman spectroscopy to study anharmonic inter- and intramolecular vibrational couplings.

09.Wed.A.4 09:30 Contributed Broadband Electronic Two-Dimensional Spectroscopy in the Deep UV Valentyn Prokhorenko1, Alessandra Picchiotti1, Samansa Maneshi1, Dwayne Miller1; 1Max Planck Institute, Germany. ABSTRACT We developed an all-reﬂ ective fully-noncollinear setup for two-dimensional electronic spectroscopy in the broadband UV (2DUV) with great phase stability (Λ/150) and applied it to the UV-chromophores dissolved in ethanol using 8-fs UV-pulses, generated in the 245-300 nm range. We are able to resolve 2D-spectra in the ~6000 cm-1 spectral window.

09.Wed.A.5 09:45 Contributed VIPER 2D-IR: A Novel Pulse Sequence to Track Exchange Beyond the Vibrational Lifetime Luuk J. van Wilderen1, Andreas T. Messmer1, Jens Bredenbeck1; 1Johann Wolfgang Goethe-University, Germany. ABSTRACT We present a new IR/UV-VIS pulse sequence that uses an IR pulse to pick a molecule within a mixture, in order to monitor its photochemistry. The beneﬁ ts of this sequence over commonly used ones discussed.

09.Wed.A.6 10:00 Contributed Characterizing phase fl uctuations of fi ber oscillators by using external optical cavities Damian N. Schimpf1, Roman Schmeissner2, Jan Schulte1, Wei Liu1, Franz X. Kärtner1, Nicolas Treps2; 1Center for Free Electron Laser Science, Deutsches Elektronen-Synchrotron, Germany; 2Laboratoire Kastler Brossel, Université Pierre et Marie Curie, CNRS, ENS, France. ABSTRACT We experimentally characterize amplitude and phase fl uctuations of a femtosecond fi ber oscillator close to the standard quantum limit. A passive cavity is employed to convert frequency noise to RIN with close to quantum-limited sensitivity.

41 ▶ TECHNICAL SESSIONS

Room A 10:45-12:30 Room B 10:45-12:30

09.Wed.B Terahertz Dynamics 09.Wed.C Electron Diffraction and Presider: Frank Hegmann Rescattering Dynamics (University of Alberta, Canada) Presider: Reika Kanya (University of Tokyo, Japan)

09.Wed.B.1 10:45 Contributed 09.Wed.C.1 10:45 Contributed Tailoring of High-Field Multi-THz Waveforms Ten-femtosecond (rms) with Sub-Cycle Precision single-electron diffraction Bernhard Mayer1, Christian Schmidt1, Johannes Bühler1, Stefan Lahme1,2, Alexander Gliserin1,2, Matthew Walbran1,2, Jonathan Fischer1, Denis V. Seletskiy1, Daniele Brida1, Ferenc Krausz1,2, Peter Baum1,2; 1Ludwig-Maximilians- Alexej Pashkin1, Alfred Leitenstorfer1; 1Deparment of Physics, Universität, Germany; 2Max-Planck-Institute of Quantum University of Konstanz, Germany. Optics, Germany. ABSTRACT Shaping of extremely intense mid-infrared transients ABSTRACT We report single-electron pulses of 12-fs/28-fs WEDNESDAY by means of time-domain slicing and frequency-domain synthesis is duration (rms/FWHM), characterized by laser streaking. A time- demonstrated. We achieve phase-stable transients with multiple MV/ resolved diffraction study on ﬁ brous graphite polycrystals reveals the cm peak fields and having single-cycle duration and strong polar practical feasibility of single-electron diffraction at potentially few- asymmetry. femtosecond resolution.

09.Wed.B.2 11:00 Contributed 09.Wed.C.2 11:00 Contributed Filling the entire Terahertz frequency gap by Laser-assisted Electron Diffraction for single-cycle MV/cm pulses Probing Femtosecond Nuclear Dynamics of Carlo Vicario1, Balazs Monoszlai1, Fernando Ardana1, Gas-phase Molecules Christoph P. Hauri1,2; 1Paul Scherrer Institut, Switzerland; Yuya Morimoto1, Reika Kanya1, Kaoru Yamanouchi1; 2Ecole Polytechnique Federale de Lausanne, Switzerland. 1Department of Chemistry, The University of Tokyo, Japan.

ABSTRACT We demonstrate highly efficient Terahertz production ABSTRACT By detecting 1 keV electrons scattered by CCl4 in a and absolute phase control in the hardly accessible THz frequency gap femtosecond laser fi eld, we observed laser-assisted electron diffraction (1-15 THz) by optical rectifi cation in organic crystals leading to single- images with which we can probe ultrafast molecular dynamics with <10 cycle fi eld oscillations beyond 150 MV/m and 0.5 Tesla. fs and ~0.01 Å resolutions.

09.Wed.B.3 11:15 Contributed 09.Wed.C.3 11:15 Contributed 0.4 mJ THz Pulses by Optical Rectifi cation Atomic-scale imaging of aligned polyatomic József A. Fülöp1,3, Zoltan Ollmann2, Csaba Lombosi2, molecules with recollision electron diffraction 4,5 4 2 Christoph Skrobol , Sandro Klingebiel , László Pálfalvi , Michael G. Pullen1, Benjamin Wolter1, Matthias Baudisch1, 4,5 4,5 1,2 1 Ferenc Krausz , Stefan Karsch , János Hebling ; MTA-PTE Michael Hemmer1, Arne Senftleben2, Claus Schroeter2, Robert 2 High-Field Terahertz Research Group, Hungary; Institute of Moshammer2, Joachim Ullrich2,3, Anh Thu Le4, Chii Dong Lin4, 3 Physics, University of Pecs, Hungary; ELI-Hu Nkft., Hungary; Jens Biegert1,5; 1ICFO-Institut de Ciencies Fotoniques, Spain; 4 5 Max-Planck-Institut für Quantenoptik, Germany; Department 2Max-Planck-Institut für Kernphysik, Germany; 3Physikalisch- für Physik, Ludwig-Maximilians-Universität, Germany. Technische Bundesanstalt, Germany; 4J. R. Macdonal Laboratory, ABSTRACT THz pulses with more than 0.4 mJ energy were Kansas State University, USA; 5ICREA-Institució Catalana de generated with 0.77% effi ciency by optical rectifi cation of 785-fs laser Recerca i Estudis Avançats, Spain. pulses in LiNbO using tilted-pulse-front pumping. The spectral peak is 3 ABSTRACT We present accurate extraction of multiple bond lengths at about 0.2 THz, suitable for charged-particle manipulation. for aligned and anti-aligned C2H2 using recollision electron diffraction. We measure bond lengths of1.20±0.06Å (C≡C) and 1.06±0.08Å (C-H).

09.Wed.B.4 11:30 Contributed Inherent Resistivity of Graphene to 09.Wed.C.4 11:30 Contributed Strong THz Fields Probing Elastic Rescattering through Dmitry Turchinovich1,2, Zoltan Mics1, Søren A. Jensen1, Half-Cycle Cutoffs in Khaled Parvez1, Ivan Ivanov1, Klaas-Jan Tielrooij3, Frank Above-Threshold Ionization Spectra 3 1 1 1 Koppens , Xinliang Feng , Klaus Müllen , Mischa Bonn ; 1 1 1 1 2 Henning Geiseler , Nobuhisa Ishii , Keisuke Kaneshima , Max Planck Inst. for Polymer Research, Germany; DTU Teruto Kanai1, Jiro Itatani1; 1Institute for Solid State Physics, Fotonik, Technical University of Denmark, Denmark; 3ICFO - University of Tokyo, Japan. The Institute of Photonic Sciences, Spain. ABSTRACT We observe photoelectron spectra from above-threshold ABSTRACT The nonlinear THz conductivity of graphene is 42 TECHNICAL SESSIONS ▶

characterized using nonlinear ultrafast THz spectroscopy. Efficient ionization of xenon using carrier-envelope phase-stabilized few-cycle carrier heating by the THz ﬁ eld reduces carrier scattering, yet, counter- pulses at 1.6 µm. The signature of elastic rescattering is imprinted on intuitively, simultaneously suppresses the high-frequency conductivity of the spectra, and through careful analysis we successfully retrieve the graphene. electron-ion backscattering cross section.

09.Wed.B.5 11:45 Contributed 09.Wed.C.5 11:45 Contributed Resonant antiferromagnetic spin Controlling Fragmentation Reactions of wave excitation by terahertz magnetic Polyatomic Molecules with near-ﬁ eld with split ring resonator Impulsive Alignment Yu Mukai1, Hideki Hirori1, Takafumi Yamamoto1, Hiroshi Xinhua Xie1, Katharina Doblhoff-Dier2, Huailiang Xu1,3, Kageyama1, Koichiro Tanaka1; 1Kyoto University, Japan. Stefan Roither1, Markus Schöffler1, Daniil Kartashov1, Sonia Erattuphuza1, Tim Rathje4, Gerhard G. Paulus4,5, Kaoru ABSTRACT A spin wave of HoFeO3 was excited by a terahertz

6 1 2 WEDNESDAY magnetic near-fi eld of a split ring resonator. The quantitative analysis Yamanouchi , Andrius Baltuška , Stefanie Gräfe , Markus shows that the spin wave was excited by the resonantly enhanced Kitzler1; 1Photonics Institute, Vienna University of Technology, magnetic fi eld. Austria; 2Institute for Physical Chemistry, Friedrich-Schiller University Jena, Germany; 3State Key Laboratory on Integrated Optoelectronics, Jilin University, China; 4Institute of Optics 09.Wed.B.6 12:00 Contributed and Quantum Electronics, Friedrich-Schiller University Jena, 5 6 Ultrafast modulation of polarization amplitude Germany; Helmholtz Institute Jena, Germany; Department of by terahertz fi elds in electronic-type Chemistry, The University of Tokyo, Japan. organic ferroelectrics ABSTRACT We experimentally and theoretically demonstrated effective control of molecular ionization and fragmentation in strong 1 1 1 Tatsuya Miyamoto , Daiki Hata , Koukichi Fujimoto , laser fi elds with impulsive alignment of a molecule. Channel selective 1 1 Hiromichi Yamakawa , Takeshi Morimoto , Masato control over molecular fragmentation reactions can be realized. Sotome1, Hiroyuki Yada1, Noriaki Kida1, Sachio Horiuchi2,3, Hiroshi Okamoto1; 1Department of Advanced Materials Science, The University of Tokyo, Japan; 2FLEC, AIST, Japan; 09.Wed.C.6 12:00 Contributed 3 CREST, JST, Japan. Attosecond spatial control of ABSTRACT Using strong terahertz fields, we succeeded in rapidly electron wave packet emission dynamics modulating ferroelectric polarizations in electronic-type ferroelectrics of Li Zhang1, Xinhua Xie1, Stefan Roither1, Yueming Zhou2, molecular crystals, TTF-CA and croconic acid. Polarization modulations 2 3 1 are attributable to collective inter- or intra-molecular charge-transfers Peixiang Lu , Xiaojun Liu , Daniil Kartashov , Markus 1 4 4 1 induced by terahertz fi eld. Schöffl er , Dror Shafi r , Paul B. Corkum , Andrius Baltuska , Igor Ivanov5, Anatoli Kheifets5, André Staudte4, Markus Kitzler1; 1Photonics Institute, Vienna University of Technology, 09.Wed.B.7 12:15 Contributed Austria; 2Wuhan National Laboratory for Optoelectronics Ultrafast photoinduced terahertz dynamics of and School of Physics, Huazhong University of Science and Technology, China; 3State Key Laboratory of Magnetic topological insulator (Bi In ) Se 1-x x 2 3 Resonance and Atomic and Molecular Physics, Chinese 1 2 2 Sim Sangwan , Matthew Brahlek , Nikesh Koirala , Academy of Sciences, China; 4Joint Laboratory for Attosecond 1 2,3 1 1 Soonyoug Cha , Seongshik Oh , Hyunyong Choi ; School Science of the National Research Council and the University of of Electrical and Electronic Engineering, Yonsei University, Ottawa, Canada; 5Research School of Physical Sciences, The Republic of Korea; 2Rutgers Center for Emergent Materials Australian National University, Australia. and Department of Physics and Astronomy, Rutgers the ABSTRACT Using orthogonally polarized two-color laser fi elds on neon 3 State University of New Jersey, USA; Institute for Advanced and coincidence momentum imaging we gain access to the Coulomb Materials, Devices and Nanotechnolog, Rutgers the State influence in single ionization on sub-cycle times, and demonstrate a University of New Jersey, USA. strong electron-electron anti-correlation in double ionization. ABSTRACT We present ultrafast terahertz dynamics in topological insulator (Bi1-xInx) 2Se3. We fi nd that photogenerated electrons suppress the increase of scattering at high temperature. The surface-bulk 09.Wed.C.7 12:15 Contributed interaction strongly depends on the dynamic condition of topological Photoionization Time Delay in phase transition. Molecular Hydrogen Sebastian Heuser1, Mazyar Sabbar1, Robert Boge1, Claudio Cirelli1, Ursula Keller1; 1ETH Zurich, Switzerland. ABSTRACT We extract the photoionization time delay difference between argon and molecular hydrogen with two complementary interferometric measurement techniques using attosecond pulses. The methods show different results, calling for different theoretical interpretations of the experimental observations.

43 ▶ TECHNICAL SESSIONS

Room A 14:00-15:45 09.Wed.D Structural Dynamics Presider: Eberhard Riedle (Ludwig-Maximillians-Universität Munchen, Germany)

09.Wed.D.1 14:00 Contributed Time-resolved X-ray absorption and emission spectroscopy on ZnO nanoparticles in solution Christopher J. Milne1, Jakub Szlachetko1,5, Tom Penfold1, Fabio Santomauro2, Alexander Britz3, Wojciech Gawelda3, Gilles Doumy4, Anne Marie March4, Steven H. Southworth4, Jochen Rittmann2, Majed Chergui2, Rafael Abela1; 1SwissFEL, Paul Scherrer Institut, Switzerland; 2Laboratoire de Spectroscopie Ultrarapide, Ecole Polytechnique Federale de Lausanne, Switzerland; 3European XFEL GmbH, Germany; 4Atomic, Molecular and Optical Physics Group, Argonne National Laboratory, USA; 5Institute of Physics, Jan Kochanowski University, Poland. ABSTRACT We have performed time-resolved resonant X-ray emission spectroscopy after UV photoexcitation of a colloidal solution of ZnO nanoparticles. The results point to electron trapping sites located at oxygen vacancies in the lattice.

WEDNESDAY 09.Wed.D.2 14:15 Contributed Tracking Electronic and Molecular Structural Dynamics during Dissociation of

the Photocatalyst Mn2(CO)10 via Time-Resolved X-Ray Spectroscopy Hana Cho1,2, Kiryong Hong2, Mathew L. Strader1, Jae Hyuk Lee1, Robert W. Schoenlein1, Nils Huse3, Tae Kyu Kim2; 1Ultrafast X-ray Science Lab, Chemical Sciences Division, Lawrence Berkeley National Laboratory, USA; 2Department of Chemistry, Pusan National University, Republic of Korea; 3Max Planck Research Department for Structural Dynamics, University of Hamburg & Center for Free Electron Laser Science, Germany. ABSTRACT The molecular structure dynamics and transient valence charge distribution during the photo-dissociation of the photocatalyst

Mn2(CO)10 are revealed via time-resolved x-ray spectroscopy at the Mn K-edge, combined with quantum chemistry simulations.

09.Wed.D.3 14:30 Contributed Excited State Structural Dynamics Probed with Time-Resolved Sulfur K-edge X-ray Absorption Spectroscopy Matthew Ross1, Benjamin E. Van Kuiken1, Mathew L. Strader2, Amy Cordones-Hahn3, Hana Cho3, Robert W. Schoenlein3, Tae Kyu Kim4, Munira Khalil1; 1Department of Chemistry, University of Washington, USA; 2SLAC National Accelerator Laboratory, USA; 3Chemical Sciences Division, Lawrence Berkeley National Laboratory, USA; 4Department of Chemistry, Pusan National University, Republic of Korea. ABSTRACT Time-Resolved X-ray absorption spectroscopy at the sulfur K-edge (~2.4 keV) is used to monitor structural dynamics following excited state proton transfer in an organosulfur molecule. The timescales of electronic structural relaxation are solvent dependent.

09.Wed.D.4 14:45 Contributed Tuning of isomerization rates in indigo-based photoswitches Elena Samoylova1, Benjamin Maerz1, Sandra Wiedbrauk2, Sven Oesterling2, Henry Dube2, Regina de Vivie-Riedle2, Wolfgang Zinth1; 1Department of Physics, Ludwig-Maximilians-University, Germany; 2Department of Chemistry, Ludwig-Maximilians- University, Germany. ABSTRACT Ultrafast excited-state dynamics in indigo-based photochromic compounds was studied with the transient absorption spectroscopy and ab initio calculations. We demonstrated an approach of adjusting excited state relaxation routes and photoisomerization rates for applications where fast photoswitching is needed.

09.Wed.D.5 15:00 Contributed Charge Migration and Molecular Dissociation Following Multiphoton Multiple Ionization of Iodine-Substitute Molecules by X-Ray Free-Electron Laser Pulses from SACLA Koji Motomura1, Edwin Kukk1,2, Kiyonobu Nagaya3,4, Satoshi Ohmura3, Hironobu Fukuzawa1,4, Shin-ichi Wada5,4, Subhendu Mondal1, Tetsuya Tachibana1, Yuta Ito1, Ryosuke Koga5, Tsukasa Sakai3, Kenji Matsunami3, Artem Rudenko6, Christophe Nicolas7, XiaoJing Liu7, Catalin Miron7, Yizhu Zhang8, Yuhai Jiang8, Jianhui Chen9, Anand Mailam10, Dong Eon Kim10, Kensuke Tono 11, Yuichi Inubushi4, Takaki Hatsui4, Makina Yabashi4, Hirohiko Kono12, Makoto Yao3, Kiyoshi Ueda1,4; 1Institute of Multidisciplinary Research for Advanced Materials, Tohoku University, Japan; 2Department of Physics and Astronomy, University of Turku, Finland; 3Department of Physics, Kyoto University, Japan; 4RIKEN SPring-8 Center, Japan; 5Department of Physical Science, Hiroshima University, Japan; 6Department of Physics, Kansas State University, USA; 7Synchrotron SOLEIL, France; 8Shanghai Advanced Research Institute, Chinese Academy of Sciences, China; 9Shanghai Institute of Applied Physics, Chinese Academy of 44 TECHNICAL SESSIONS ▶

Sciences, China; 10Department of Physics, CASTECH, MPC-AS, POSTECH, Republic of Korea; 11Japan Synchrotron Radiation Research Institute (JASRI), Japan; 12Department of Chemistry, Tohoku University, Japan. ABSTRACT We have studied charge migration and dissociation in iodine-contained molecules using XFEL from SACLA and applying the ion momentum coincidence technique to fragmentation of highly charged molecular ions produced via XFEL at the iodine site.

09.Wed.D.6 15:15 Contributed Signatures of Conical Intersection Mediated Relaxation Dynamics in Time-Resolved Broadband Raman Detection Benjamin Fingerhut1, Konstantin E. Dorfman2, Shaul Mukamel2; 1Max-Born-Institut für Nichtlineare Optik und Kurzzeitspektroskopie, Germany; 2Chemistry, University of California, Irvine, USA. ABSTRACT Ab-Initio simulations of Raman signals reveal the excited state deactivation mechanism of uracil. The signals provide sub- molecular sensitivity of out-of-plane displacements during conical intersection mediated relaxation and properly describe the time-resolution of the techniques. WEDNESDAY

09.Wed.D.7 15:30 Contributed Femtosecond Electron Diffraction Study of the Spin Crossover Dynamics of II Crystalline [Fe (bpy)3][PF6 ] 2 Yifeng Jiang1, Donald Kelloway2, Meng Gao2, Lai Chung Liu2, Cheng Lu2, Wojciech Gawelda3, Dwayne Miller1,2; 1Physics and Chemistry, Max Planck Institute for the Structure and Dynamics of Matter, University of Hamburg, Centre for Free Electron Laser Science, DESY, Germany; 2Physics and Chemistry, University of Toronto, Canada; 3European XFEL GmbH, Germany.

II ABSTRACT The atomic motions involved in spin crossover dynamics of crystalline [Fe (bpy)3][PF6]2 are investigated by femtosecond electron diffraction (FED). The experiment was performed by an ultrabright femtosecond electron source using 3.0×105 electrons per pulse with 400 fs temporal instrument response function.

Exhibition Hall 15:45-17:15

09.Wed.P3 Poster Session III

09.Wed.P3.1 Terahertz imaging with optical resolution by femtosecond laser fi lament in air Weiwei Liu1, Jiayu Zhao1, Lanjun Guo1; 1Nankai University, China. ABSTRACT We introduce a superresolution resolution THz imaging technique which uses the THz radiation generated by a femtosecond laser fi lament in air as the probe, based on the fact that the femtosecond laser fi lament forms a waveguide for the THz wave in air.

09.Wed.P3.2 Recombination-induced autoionization process in rare-gas clusters Bernd Schuette1, Mathias Arbeiter2, Thomas Fennel2, Filippo Campi3, Marc J. J. Vrakking1, Arnaud Rouzée1; 1Max-Born- Institut, Germany; 2Universität Rostock, Germany; 3Lund University, Sweden. ABSTRACT We investigate electron-ion recombination to excited states in atomic clusters exposed to intense NIR and XUV pulses, which leads to a yet undiscovered autoionization mechanism as a consequence of multiple recombination processes.

09.Wed.P3.3 Multiphoton Multiple Ionization of Rare-Gas Atoms and Clusters by X-Ray Free-Electron Laser Pulses from SACLA Hironobu Fukuzawa1,2, Koji Motomura1, Tetsuya Tachibana1, Zoltan Jurek3, Sang-Kil Son3, Per Johnsson4, Kiyonobu Nagaya5,2, Marco Siano6, Shin-ichi Wada7,2, Subhendu Mondal1, Miku Kimura1, Yuta Ito1, Tsukasa Sakai5, Kenji Matsunami5, Hironori Hayashita7, Jumpei Kajikawa7, XiaoJing Liu8, Emmanuel Robert8, Catalin Miron8, Raimund Feifel9, Edwin Kukk10, Benedikt Rudek11,12, Benjamin Erk11,12, Lutz Foucar11,13, Jonathan P. Marangos6, Kensuke Tono14, Yuichi Inubushi2, Takaki Hatsui2, Makina Yabashi 2, Beata Ziaja3,15, Robin Santra3,16, Makoto Yao5, Kiyoshi Ueda1,2; 1Institute of Multidisciplinary Research for Advanced Materials, Tohoku University, Japan; 2RIKEN SPring-8 Center, Japan; 3Center for Free-Electron Laser Science (CFEL), DESY, Germany; 4Department of Physics, Lund University, Sweden; 5Department of Physics, Kyoto University, Japan; 6Blackett Laboratory, Imperial College London, United Kingdom; 7Department of Physical Science, Hiroshima University, Japan; 8Synchrotron SOLEIL, 45 ▶ TECHNICAL SESSIONS

France; 9Department of Physics and Astronomy, Uppsala University, Sweden; 10Department of Physics and Astronomy, University of Turku, Finland; 11Max-Planck Advanced Study Group at CFEL, Germany; 12Max-Planck-Insitut für Kernphysik, Germany; 13Max- Planck-Insitut für medizinische Forschung, Germany; 14Japan Synchrotron Radiation Research Institute (JASRI), Japan; 15Institute of Nuclear Physics, PAS, Poland; 16Department of Physics, University of Hamburg, Germany. ABSTRACT We have investigated multiphoton multiple ionization dynamics of rare-gas atoms and clusters by 5 keV and 5.5 keV x-ray free- electron laser (XFEL) pulses provided by a new XFEL facility, SACLA in Japan.

09.Wed.P3.4 Attosecond Frequency Resolved Momentum Imaging of Two-photon Dissociative Ionization Dynamics of Nitrogen Molecule Tomoya Okino1, Yusuke Furukawa1, A. Amani Eilanlou1, Yasuo Nabekawa1, Eiji J. Takahashi1, Kaoru Yamanouchi2, Katsumi Midorikawa1; 1RIKEN, Japan; 2University of Tokyo, Japan. ABSTRACT Two-photon dissociative ionization processes of nitrogen molecule are investigated with attosecond nonlinear Fourier transformation spectroscopy. The frequency resolved momentum images extracted from delay dependent momentum images showed attosecond nonlinear response of nitrogen molecule.

WEDNESDAY 09.Wed.P3.5 Photoelectron angular distributions in EUV+IR two-color near-threshold ionization of Ne and He Subhendu Mondal1, Hironobu Fukuzawa1,2, Koji Motomura1, Tetsuya Tachibana1, Kiyonobu Nagaya2,3, Tsukasa Sakai3, Kenji Matsunami3, Satoshi Yase3, Makoto Yao3, Shin-ichi Wada2,4, Hironori Hayashita4, Norio Saito2,5, Carlo Callegari6, Kevin Prince6, Catalin Miron7, Patrick O’Keeffe8, Paola Bolognesi8, Lorenzo Avaldi8, Mitsuru Nagasono2, Tadashi Togashi2,9, Makina Yabashi2, Kenichi L. Ishikawa10, Andrey Kazansky11, Nikolay Kabachnik1,12, Kiyoshi Ueda1,2; 1Institute of Multidisciplinary Research for Advanced Materials, Tohoku University, Japan; 2RIKEN SPring-8 Center, Japan; 3Department of Physics, Kyoto University, Japan; 4Department of Physics, Hiroshima University, Japan; 5National Institute of Advanced Industrial Science and Technology, Japan; 6Elettra-Sincrotrone, Italy; 7Synchrotron SOLEIL, France; 8CNR-Istituto di Metodologie Inorganiche e dei Plasmi, Italy; 9Japan Synchrotron Radiation Research Institute, Japan; 10Photon Science Center, The University of Tokyo, Japan; 11Basque Foundation for Science, Spain; 12Skobelsyn Institute of Nuclear Physics, Lomonosov Moscow State University, Russian Federation. ABSTRACT Photoelectron angular distributions (PADs) dependence on the time-delay between EUV-FEL and IR laser pulses is observed for ionization of Ne. PADs for Rydberg excited one- and two-IR photon above-threshold ionization of He are measured.

09.Wed.P3.6 Controlling attosecond electron wave packet in a molecule Hiromichi Niikura1; 1Applied Physics, Waseda University, Japan. ABSTRACT We control and identify the two-channel interference and the attosecond electron wave packet in polyatomic molecules by using two- dimensional high-harmonic spectra emitted from aligned molecules using the orthogonally polarized, two color laser ﬁ elds.

09.Wed.P3.7 High-order Harmonics Fourier Transform Spectroscopy of Two-Photon Dissociative Ionization of Hydrogen Molecules Yusuke Furukawa1, Tomoya Okino1, Yasuo Nabekawa1, A. Amani Eilanlou1, Eiji J. Takahashi1, Kaoru Yamanouchi2, Katsumi Midorikawa1; 1RIKEN Center for Advanced Photonics, Japan; 2The University of Tokyo, Japan. ABSTRACT We have investigated two-photon dissociative ionization processes induced by high-order harmonic generation pulses with Fourier transform spectroscopy. Delay-dependent kinetic energy distribution of fragment ions reveals dissociative ionization dynamics of hydrogen molecules.

09.Wed.P3.8 Experimental Evidence of Light Induced Conical Intersections in Dissociation of Diatomic Molecules Adi Natan1,2, Matthew R. Ware1,2, Philip H. Bucksbaum1,2; 1Stanford PULSE Institute, SLAC National Accelerator Laboratory, USA; 2Physics, Stanford University, USA.

+ ABSTRACT We present evidence for the effect of light induced conical intersections in strong ﬁ eld photodissociation of H2 , manifested in angular distribution modulations that result from the topological singularity induced by intense laser pulses.

46 TECHNICAL SESSIONS ▶

09.Wed.P3.9 Photomechanical effects on femtosecond-laser ablation of fused silica studied using time-resolved reﬂ ectivity Takayuki Kumada1, Hiroshi Akagi1, Ryuji Itakura1, Tomohito Otobe1, Atsushi Yokoyama1; 1Japan Atomic Energy Agency, Japan. ABSTRACT We observed oscillation of time-resolved reflectivity of femtosecond-laser-ablated fused silica. We ascribe the oscillation to the interference between probe pulses reﬂ ected from a sample surface and a thin layer produced by the photomechanical effect.

09.Wed.P3.10 Investigation of vibrational dynamics by femtosecond time-resolved CARS Yuanqin Xiia1, Zhao Yang1, Sheng Zhang2, Ping He3, Zhiwei Dong1, Deying Chen1, Zhonghua Zhang1; 1National Key Laboratory of Science and Technology on Tunable Laser, Harbin Institute of Technology, China; 2Department of Physics, Harbin Institute of 3 Technol, China; College of Foundation Science, Harbin University of Commerce, China. WEDNESDAY ABSTRACT We report the femtosecond time-resolved CARS in BBO crystal, ethanol, cresyl violet 670 and pyrromethene 650 using the various degrees of freedom such as the timing, polarization and wavelengths of the laser pulses.

09.Wed.P3.11 The primary photosynthetic energy conversion in bacterial reaction centers - Stepwise electron transfer and the effect of elevated exposure levels Pablo Nahuel Dominguez1, Matthias Himmelstoss1, Jeff Michelmann1, Florian Lehner1, Alastair Gardiner2, Richard Cogdell2, Wolfgang Zinth1; 1Lehrstuhl für BioMolekulare Optik, Ludwig-Maximilians-Universität, Germany; 2Institute of Molecular Cell and Systems Biology, University of Glasgow, United Kingdom. ABSTRACT The primary reaction in photosynthetic reaction centers from Rhodobacter sphaeroides is investigated for different experimental conditions. Agreement with stepwise electron transfer via a reduced bacteriochlorophyll was observed at low excitation rates.

09.Wed.P3.12 Ultrafast E to Z Photoisomerization of Chiral Biomimetic Molecular Switches Moussa Gueye1, Stefan Haacke1, Stefania Fusi2, Massimo Olivucci2,3, Etienne Gindensperger4, Jérémie Léonard1; 1IPCMS, CNRS - Université de Strasbourg, France; 2Dipartimento di Chimica, Università degli Studi di Siena,, Italy; 3Chemistry Department, Bowling Green State University, USA; 4Laboratoire de Chimie Quantique, Institut de Chimie, CNRS - Université de Strasbourg, France. ABSTRACT Transient absorption spectroscopy on chiral biomimetic molecular switches reveals a critical and novel influence of methyl substitutions on the photoreaction speed and on the observation of vibrational coherence in both isomerization directions.

09.Wed.P3.13 Femtosecond Vibrational Spectroscopic Study on Photoexcitation Dynamics of DNO-bound Myoglobin Taegon Lee1, Seongchul Park1, Manho Lim1; 1Pusan National University, Republic of Korea. ABSTRACT Time-resolved vibrational spectra of DNO-bound myoglobin showed instantaneous bleach that decays on a picosecond time scale, suggesting that most of the photoexcited MbDNO undergoes picosecond geminate rebinding of DNO to Mb after its immediate deligation.

09.Wed.P3.14 Toward Ultrafast In Situ X-Ray Studies of Interfacial Photoelectrochemistry Stefan Neppl1,2, Yi-Sheng Liu3, Chenghao Wu4,6, Andrey Shavorskiy2, Ioannis Zegkinoglou2, Tyler Troy2, Daniel S. Slaughter2, Musa Ahmed2, Anton S. Tremsin5, Jinghua Guo3, Per-Anders Glans3, Miquel Salmeron4, Hendrik Bluhm2, Oliver Gessner1,2; 1Ultrafast X-ray Science Laboratory, Lawrence Berkeley National Laboratory, USA; 2Chemical Sciences Division, Lawrence Berkeley National Laboratory, USA; 3Advanced Light Source, Lawrence Berkeley National Laboratory, USA; 4Materials Sciences Division, Lawrence Berkeley National Laboratory, USA; 5Space Sciences Laboratory, University of California, USA; 6Department of Chemistry, University of California, USA. ABSTRACT Picosecond time-resolved in situ X-ray absorption and X-ray photoelectron spectroscopy techniques for atomic site-speciﬁ c real- time studies of interfacial photoelectrochemistry are developed. First experiments monitor electronic dynamics of dye-sensitized nanocrystals and at hematite-electrolyte interfaces.

47 ▶ TECHNICAL SESSIONS

09.Wed.P3.15 Elementary Electron and Ion Dynamics in Ionized Liquid Water Jialin Li1, Zhaogang Nie1, Yi Ying Zheng1, Shuo Dong1, Zhi-Heng Loh1; 1School of Physical and Mathematical Sciences, Nanyang Technological University, Singapore. ABSTRACT Polarization-resolved femtosecond coherence spectroscopy is used to observe the dealignment of the injected electron, hole orbital + motion, solvent reorganization, and ballistic proton transport in ionized liquid water. The lifetime of the H2O cation is also determined.

09.Wed.P3.16 Ultrafast IR Spectroscopy of O-H Stretching Modes in 2-Naphthol-Acetonitrile Photoacid-Base Complexes Brian T. Psciuk1, Mirabelle Prémont-Schwarz2, Benjamin Koeppe2, Sharon Keinan3, Dequan Xiao1,4, Victor S. Batista1, Erik T.J. Nibbering2; 1Department of Chemistry, Yale University, USA; 2Max Born Institut fuer Nichtlineare Optik and Kurzzeitspektroskopie, Germany; 3Department of Chemistry, Ben-Gurion University of the Negev, Israel; 4Department of Chemistry & Chemical Engineering, University of New Haven, USA. ABSTRACT The O-H stretching mode is a direct hydrogen-bond probe. In a combined femtosecond IR spectroscopic and quantum chemical approach, we demonstrate how this local marker directly reﬂ ects charge distribution changes induced in photoexcited photoacid-base complexes. WEDNESDAY

09.Wed.P3.17 12 13 Intense Field Ionization of C2H2 and C CH2 Aligned in Field-free Space Hirokazu Hasegawa1, Yuki Ikeda2, Kotaro Sonoda1, Takahiro Sato2, Atsushi Iwasaki2, Kaoru Yamanouchi2; 1Department of Integrated Sciences, University of Tokyo, Japan; 2Department of Chemistry, University of Tokyo, Japan.

ABSTRACT Intense field ionization of nonadiabatically aligned C2H2 was investigated by a pump-probe technique. The yield of parent ions revealed that the ionization occurs preferentially when the molecular axis is perpendicular to the laser polarization direction.

09.Wed.P3.18 Survival of Nuclear Coherences for a Series of Internal Conversions in Free Base Tetraphenylporphyrin So Young Kim1, Sangkyu Kim2, Taiha Joo1; 1Department of Chemistry, POSTECH, Republic of Korea; 2Department of Chemistry, KAIST, Republic of Korea. ABSTRACT The stepwise internal conversions in free base tetraphenylporphyrin generate coherent nuclear wave-packets in both Q states. Theory and experiment show that the observed wave-packet motions involve out-of-plane vibration of the porphyrin ring that is strongly coupled to internal conversions.

09.Wed.P3.19 Ultrafast Intramolecular Charge Transfer Process of Asymmetric 9,9’-Bianthryl derivative in Ionic Liquid Eisuke Takeuchi1, Masayasu Muramastu1, Tetsuro Katayama1,2, Syoji Ito1, Yutaka Nagasawa1,2, Hiroshi Miyasaka1,2; 1Osaka university, Japan; 2Japan Science and Technology Agency (JST), Japan. ABSTRACT Femtosecond transient absorption spectroscopy revealed that initial ultrafast charge transfer process of asymmetric 10-cyano-9,9’- bianthryl in ionic liquid occurs in the sub-100 femtosecond domain which is much faster than that of symmetric 9,9’-bianthryl.

09.Wed.P3.20 Ultrafast Dynamics of a Bistable Intramolecular Proton Transfer Switch Julia Bahrenburg1, Michal F. Rode2, Andrzej L. Sobolewski2, Friedrich Temps1; 1Institute of Physical Chemistry, Germany; 2Institute of Physics, Poland. ABSTRACT The stepwise formation of the proton transfer product of a bistable molecular switch was unambiguously revealed by femtosecond ﬂ uorescence and absorption spectroscopy. The interpretation was supported by ab initio excited-state calculations.

09.Wed.P3.21 Decomposition of Cyclohexane Ion Induced by Intense Femtosecond Laser Fields Takao Yamazaki 1, Reika Kanya1, Kaoru Yamanouchi1; 1Department of Chemistry, School of Science, The University of Tokyo, Japan. ABSTRACT Decomposition of cyclohexane cations induced by an intense femtosecond laser field was investigated by ion trap time- of-flight mass-spectrometry. Laser intensity dependences of the yields of fragment ions revealed decomposition pathways producing the 48 respective fragment ions. TECHNICAL SESSIONS ▶

09.Wed.P3.22 Attosecond Stimulated X-ray Raman Probes of Energy and Electron Transfer in Porphyrin Dimers and Proteins Yu Zhang1, Jason D. Biggs1, Daniel Healion1, Konstantin E. Dorfman1, Weijie Hua1, Shaul Mukamel1; 1University of California, Irvine, USA. ABSTRACT Energy and electron transfer processes in molecular complexes can be measured at unprecedented spatial and temporal resolution by novel X-ray spectroscopy techniques. Multidimensional broadband X-ray signals are simulated for a metalloporphyrin dimer and a Re-modiﬁ ed azurin model system of long-range biological electron transfer.

09.Wed.P3.23 Ultrafast Coulomb Explosion of Formaldehyde in 7 and

35 fs Intense Laser Fields Studied by Triple Ion-Coincidence Momentum Imaging WEDNESDAY Chien-Ming Tseng1, Akitaka Matsuda1,2, Mizuho Fushitani1,2, Akiyoshi Hishikawa1,2; 1Institute for Molecular Science, National Institutes of Natural Sciences, Japan; 2Nagoya University, Japan.

ABSTRACT Ultrafast three-body Coulomb explosion of formaldehyde (H2CO) in intense laser fields has been studied. The pulse duration dependence of the Newton plot of the fragment ions revealed the ultrafast molecular dynamics in the dication states.

09.Wed.P3.24 Interpreting Coherence Beats in Numerically Exact Simulations of 2D Electronic Spectra Daniele Monahan1, Lukas Whaley-Mayda1, Akihito Ishizaki2, Graham R. Fleming1; 1Chemistry, University of California, USA; 2Institute for Molecular Science, National Institutes of Natural Sciences, Japan. ABSTRACT Coherence beats are simulated in a numerically exact hierarchy method treatment of an electronic heterodimer coupled to a vibration and bath. We vary coupling parameters to analyze the lifetimes and contributions from different Liouville pathways.

09.Wed.P3.25 Elucidation and Control of Ultrafast Intramolecular Charge Transfer Dynamics of Marine Photosynthetic Pigments Daisuke Kosumi1, Takayuki Kajikawa2, Satoshi Okumura2, Koki Yano2, Mitsuru Sugisaki1, Kazuhiko Sakaguchi1, Shigeo Katsumura2, Hideki Hashimoto1; 1Osaka City University, Japan; 2Kwansei Gakuin University, Japan. ABSTRACT Ultrafast Intramolecular Charge Transfer (ICT) state dynamics of fucoxanthin have been investigated by femtosecond pump-probe measurements. A modiﬁ cation of conjugated polyene chain length of fucoxanthin enabled us to clarify and control an ICT character.

09.Wed.P3.26 Ultrafast energy and charge transfer processes in a ﬂ exible molecular triad designed for organic photovoltaics Thomas Roland1, Li Liu1, Elodie Heyer2, Adrian Ruff3, Sabine Ludwigs3, Raymond Ziessel2, Stefan Haacke1; 1DON, CNRS - IPCMS, France; 2LCOSA, CNRS - ICPEES, France; 3IPOC, Stuttgart University, Germany. ABSTRACT A detailed spectro-temporal analysis of the ultrafast transient absorption and fluorescence signals allows deciphering multiple energy and charge transfer processes in a light-harvesting molecular triad designed as photo-sensitizing unit featuring a novel BODIPY compound.

09.Wed.P3.27 Inﬂ uence of Intramolecular Hydrogen Bonding on the Photodynamics of 2-(1-Ethynylpyrene)-Adenosine (PyA) Peter Trojanowski1, Christian Grünewald2, Franziska Graupner3, Markus Braun1, Andreas J. Reuss1, Joachim W. Engels2, Josef Wachtveitl1; 1Institute of Physical and Theoretical Chemistry, Johann Wolfgang Goethe-University, Germany; 2Institute of Organic Chemistry and Chemical Biology, Johann Wolfgang Goethe-Universität, Germany; 3Faculty of Physics, Center for Integrative Protein Science, Ludwig Maximilians University Munich, Germany. ABSTRACT We report on the inﬂ uence of intramolecular hydrogen bonding between the 2’OH group of ribose and adenine in 2-(1-ethynylpyrene)- adenosine (PyA) on the ultrafast dynamics, by comparing PyA with its deoxy derivate (PydA).

49 ▶ TECHNICAL SESSIONS

09.Wed.P3.28 Exciton dynamics in Cu-doped InAs colloidal quantum dots Chunfan Yang1, Itay Gdor1, Yorai Amit2, Adam Faust2, Uri Banin2, Sanford Ruhman1; 1The Institute of chemistry and Farkas Center for Light Induced Processes Hebrew University, Israel; 2The institute of Chemistry and the Center for Nanoscience and Nanotechnology Hebrew University, Israel. ABSTRACT Femtosecond transient absorption spectroscopy has been used to investigate the exciton dynamics in native and Cu-doped InAs quantum dots from three respects: 1) Auger recombination; 2) hot exction cooling; 3) absorption cross section.

09.Wed.P3.29 Nonlinear Carrier Dynamics in Semi-Metal Bismuth Induced by Intense Terahertz Field Kotaro Araki1, Yasuo Minami1, Thang D. Dao2,3, Tadaaki Nagao2,3, Jun Takeda1, Masahiro Kitajima4,5, Ikufumi Katayama1; 1Yokohama National University, Japan; 2National Institute for Materials Science, Japan; 3Japan Science and Technology Agency, Japan; 4LxRay Co. Ltd, Japan; 5National Defense Academy, Japan. ABSTRACT We investigated nonlinear carrier response of semi-metal bismuth under intense terahertz pulse illumination. By applying the intense terahertz ﬁ eld, the transmittance increases more than 10 %, indicating an increase of the effective mass. WEDNESDAY 09.Wed.P3.30 A nanoscale vacuum-tube diode triggered by few-cycle laser pulses Takyua Higuchi 1, Peter Hommelhoff1; 1Lehrstuhl fuer Laserphysik, Friedrich-Alexander-Universitaet Erlangen-Nuernberg, Germany. ABSTRACT We propose and demonstrate a nanoscale vacuum-tube diode consisting of two metal nano-tips as an ultrafast electronic device employing pulsed electrons emitted by few-cycle photoemission.

09.Wed.P3.31 Collapse and revival of large-amplitude coherent phonons: polarization interference versus quantum beats Oleg Misochko1, Michael V. Lebedev1, Kunie Ishioka2; 1Institute of Solid State Physics, Russian Academy of Sciences, Russian Federation; 2National Institute for Materials Science, Japan. ABSTRACT We report femtosecond time-resolved measurements of lattice dynamics in Bi made at helium temperature over a wide range of

excitation levels. We demonstrate that the collapse/revival of large-amplitude A1g coherent phonons is a polarization interference arising due to laterally inhomogeneous excitation

09.Wed.P3.32

Magnetically induced Lattice Dynamics in a Magnetoelectric Antiferromagnet Cr2O3 Tomohisa Nishimoto1, Takeshi Moriyasu1, Toshiro Kohmoto1; 1Kobe University, Japan.

ABSTRACT We studied the optically induced lattice dynamics in a magnetoelectric antiferromagnet Cr2O3 by polarization spectroscopy. The observed divergence behavior of the relaxation rate at the Néel temperature suggests the correlation between lattice and spin ﬂ uctuations.

09.Wed.P3.33

Exciton recombination dynamics in type II CdTe-Cu2-xTe nano heterostructures with excitonic and plasmonic properties Ilka Kriegel1,2, Andreas Wisnet4, Ajay R. Kandada5, Francesco Scotognella3, Francesco Tassone5, Christina Scheu4, Hui Zhang6, Alexander O. Govorov6, Jessica Rodríguez-Fernández1,2, Jochen Feldmann1,2; 1Photonics and Optoelectronics Group, Department of Physics and CeNS, Ludwig-Maximilians-Universität München, Munich, Germany; 2Nanosystems Initiative Munich (NIM), Germany; 3Dipartimento di Fisica, Politecnico di Milano, Italy; 4Department of Chemistry and CeNS, Ludwig-Maximilians- Universität München, Gabon; 5CNST of IIT@POLIMI, Iceland; 6Department of Physics and Astronomy, Ohio University, USA.

ABSTRACT A faster exciton recombination dynamics in type II CdTe-Cu2-xTe nano-heterostructures occurs with increasing the size of the

Cu2-xTe subdomain. We suggest that an Auger mediated recombination pathway due to the free carriers in the vacancy-doped Cu2-xTe subunit is the main reason for the faster dynamics.

09.Wed.P3.34

Anomalous phase change process in [(GeTe)2/(Sb2Te 3 )]20 superlattice observed by coherent phonon spectroscopy Kotaro Makino1, Yuta Saito1, Kirill Mitrofanov1, Junji Tominaga1, Alexander Kolobov1, Takashi Nakano1, Paul Fons1, Muneaki 50 TECHNICAL SESSIONS ▶

Hase2; 1Nanoelectronics Research institute, National Institute of Advanced Industrial Science, Japan; 2Institute of Applied Physics, University of Tsukuba, Japan.

ABSTRACT The temperature-dependent ultrafast lattice dynamics of topological (GeTe)2/(Sb2Te 3) superlattice phase change memory material was investigated. By comparing with Ge-Sb-Te alloy, a clear contrast suggesting the unique phase change behavior was found.

09.Wed.P3.35 Coherent ultrafast magnetization dynamics non-resonantly induced in cobalt by an intense Terahertz transient Fernando Ardana1,2, Carlo Vicario1, Peter Derlet1, Barati Tudu3, Jan Luning3, Christoph P. Hauri1,2; 1Paul Scherrer Institut, Switzerland; 2Ecole Polytechnique Federale de Lausanne, Switzerland; 3UPMC, France. ABSTRACT We demonstrate non-resonant magnetization dynamics in the ferromagnetic cobalt thin ﬁ lm induced by a record high-ﬁ eld Terahertz pulse. The magnetization dynamics are coherent and exactly follow the THz carrier oscillations. WEDNESDAY

09.Wed.P3.36 Ab Initio Solution of Structural Dynamics with Ultrafast Electron Diffraction and Charge Flipping Lai Chung Liu1,2, Meng Gao1,2, Yifeng Jiang2, Cheng Lu1, Manabu Ishikawa3, Hideki Yamochi3, Dwayne Miller1,2; 1Physics, University of Toronto, Canada; 2Max Planck Institute for the Structure and Dynamics of Matter, Germany; 3Research Center for Low Temperature and Materials Sciences, Kyoto University, Japan.

ABSTRACT Ultrafast electron diffraction is used to probe the photoinduced structural dynamics of single crystal (EDO-TTF)2PF6 with femtosecond time resolution. Structure factor phases at key time points are solved ab initio using the charge-ﬂ ipping method.

09.Wed.P3.37 Velocity Map Imaging of Electrons Strong-Field Photoemitted from Si-Nanotip Hong Ye1,2, Jens M. Kienitz1,3, Shaobo Fang1,3, Sebastian Trippel1, Michael Swanwick4, Phillip D. Keathley5, L. F. Velásquez- García4, Giovanni Cirmi1,3, Giulio Rossi1,2, Arya Fallahi1,3, Oliver D. Mücke1,3, Jochen Küpper1,2, Franz X. Kärtner1,5; 1Center for Free-Electron Laser Science, Deutsches Elektronen-Synchrotron DESY, Germany; 2Physics Department, University of Hamburg, Germany; 3The Hamburg Centre for Ultrafast Imaging, Germany; 4Microsystems Technology Laboratories, Massachusetts Institute of Technology, USA; 5Department of Electrical Engineering and Computer Science and Research Laboratory of Electronics, Massachusetts Institute of Technology, USA. ABSTRACT We observe for the ﬁ rst time electron velocity/momentum distribution of three-photon ionization and strong-ﬁ eld photoemission from Si-nanotip arrays using solid-state velocity map imaging.

09.Wed.P3.38 Quantum interference between electron-phonon coupled states in bulk gallium arsenide Kazutaka Nakamura1,2, Shingo Hayashi1,2, Keigo Kato1,2, Katsura Norimatsu1,2, Masaki Hada1,3, Yosuke Kayanuma1,2; 1Tokyo Institute of Technology, Japan; 2CREST-JST, Japan; 3PRESTO-JST, Japan. ABSTRACT We observed quantum interference between electron-phonon coupled states in a bulk GaAs by using two phase-locked femtosecond pulses and found that the electronic coherence remains within ~ 45 fs even at room temperature.

09.Wed.P3.39 Laser-Induced Plasma Dynamics Imaged by Femtosecond In-Line Holography Neeke Rothe1, Christoph Merschjann1, Conrad Schuster1, Thomas Fennel1, Stefan Lochbrunner1; 1Institute of Physics, University of Rostock, Germany. ABSTRACT The microplasma evolution in 30nm Au-foils driven by 800nm pump pulses is imaged via in-line holography using delayed 400nm probe pulses. Time-resolved optical properties are extracted via numerical inversion of scattering images.

09.Wed.P3.40 Photoinduced insulating of layered organic metal driven by strong electric ﬁ eld of 1.5-cycle, 7 fs infrared pulse Shinichiro Iwai1,2, Takahiro Ishikawa1, Yuto Sagae1, Yota Naito1, Junichi Ichimura1, Yohei Kawakami1, Hirotake Itoh1,2, Sumio Ishihara1, Kaoru Yamamoto3, Kyuya Yakushi4, Takahiko Sasaki5,2, Hideo Kishida6,2, Kenji Yonemitsu7; 1Physics, Tohoku University, Japan; 2CREST, JST, Japan; 3Applied Physics, Okayama Science University, Japan; 4Toyota Physical and Chemical Research, Japan; 5Institute for Materials Research, Tohoku University, Japan; 6Applied Physics, Nagoya University, Japan; 7Physics, Chuo University, Japan. 51 ▶ TECHNICAL SESSIONS

ABSTRACT Photoinduced metal to insulator (M-I) change are driven by coherent electron oscillation under strong electric ﬁ led (10 MV/cm) of 1.5-cycle (7 fs) near infrared light. Threshold for the M-I change decrease near the M-I transition temperature.

09.Wed.P3.41 Ultrafast optical modulation of efﬁ ciently-generated terahertz-wave in charge ordered organic ferroelectrics Hirotake Itoh1,2, Keisuke Itoh1, Kazuki Goto1, Junichi Ichimura1, Yota Naito1, Kaoru Yamamoto3, Kyuya Yakushi4, Hideo Kishida5,2, Shinichiro Iwai1,2; 1Department of Physics, Tohoku University, Japan; 2JST, CREST, Japan; 3Department of Physics, Okayama University of Science, Japan; 4Toyota Physical and Chemical Research Institute, Japan; 5Department of Applied Physics, Nagoya University, Japan.

ABSTRACT Terahertz-wave generation in organic ferroelectrics α-(ET)2I 3 is over 70 times more efﬁ cient than prototypical ZnTe. Ultrafast (< 0.1 ps) and sensitive (~ 40 %) photoresponse of the terahertz wave results from strongly-correlated electrons therein.

09.Wed.P3.42 Ultrafast dynamics in epitaxial silicene on Ag(111) Eugenio Cinquanta1, Stefano Dal Conte2, Daniele Chiappe1, Carlo Grazianetti1, Marco Fanciulli1,3, Alessandro Molle1, Giulio WEDNESDAY Cerullo2,4, Salvatore Stagira4, Francesco Scotognella4, Caterina Vozzi2; 1Laboratorio MDM, IMM-CNR, Italy; 2Institute for Photonics and Nanotechnologies, CNR, Italy; 3Dipartimento di Scienza dei Materiali, Università degli Studi di Milano-Bicocca, Italy; 4Department of Physics, Politecnico di Milano, Italy. ABSTRACT Ultrafast transient reﬂ ectivity measurements were performed in epitaxial 4x4 silicene grown on Ag(111). Comparison with bulk silicon and silver response highlighted the occurrence of peculiar photo-physical mechanisms, suggesting a metallic-like behavior in silicene.

09.Wed.P3.43 Electric and Magnetic Responses in Nonlinear Terahertz Metamaterials Harold Y. Hwang1,2, Nathaniel C. Brandt1, Kebin Fan2, Xin Zhang2, Richard D. Averitt3, Keith Nelson1; 1Massachusetts Institute of Technology, USA; 2Department of Mechanical Engineering, Boston University, USA; 3Department of Physics, Boston University, USA. ABSTRACT We report THz electric and magnetic fi eld-induced nonlinear responses in metamaterial structures. We demonstrate air breakdown in SiNx metamaterials with THz electric fi elds, and highly nonlinear responses in 3D silicon metamaterials with THz magnetic fi elds.

09.Wed.P3.44

Extreme Ultraviolet Transient Grating Measurement of Insulator-Metal Transition Dynamics of VO2 Emily F. Sistrunk1, Jakob Grilj1,2, Jaewoo Jeong3, Mahesh G. Samant3, Alexander X. Gray4, Hermann A. Durr4, Stuart S. Parkin3, Markus Gühr1; 1Stanford PULSE Institute, SLAC National Accelerator Laboratory, USA; 2Laboratory of Ultrafast Spectroscopy, Ecole Polytechnique Federal de Lausanne, Switzerland; 3IBM Almaden Research Center, USA; 4Stanford Institute for Materials and Energy Sciences, SLAC National Accelerator Laboratory, USA. ABSTRACT We demonstrate spectrally resolved transient grating spectroscopy in the extreme ultraviolet near the M-edge of vanadium dioxide. Time-dependent measurements of the ultrafast photo-induced insulator-to-metal transition disentangle pure electronic response from electron- phonon coupling and thermal effects.

09.Wed.P3.45 Laser streaking of free-electron pulses at 25 keV Alexander Gliserin1,2, Friedrich O. Kirchner1,2, Matthew Walbran1,2, Ferenc Krausz1,2, Peter Baum1,2; 1Max-Planck-Institute of Quantum Optics, Germany; 2Ludwig-Maximilians-Universität, Germany. ABSTRACT We demonstrate an optical-field-driven streak camera for temporal characterization of ultrashort free-electron pulses with sub- ångström de Broglie wavelength. This metrology reveals duration, chirp, and coherence of diffraction-capable electron pulses and potentially offers attosecond resolution.

09.Wed.P3.46 Isolating Quantum Coherence using Coherent Multi-dimensional Spectroscopy with Spectrally Shaped Pulses Jonathan O. Tollerud1, Christopher R. Hall1, Jeffrey A. Davis1; 1Swinburne University of Technology, Australia. ABSTRACT We demonstrate how spectral shaping in coherent multidimensional spectroscopy can isolate specific signal pathways and directly access quantitative details. We identify, isolate and analyse weak coherent coupling between spatially separated excitons in asymmetric double quantum-wells. 52 TECHNICAL SESSIONS ▶

09.Wed.P3.47 Few-Cycle Laser Pulse induced Plasmon Assisted Thermionic Injection in Metal-Insulator-Metal Junctions Matthias Hensen1, Dominik Differt1, Ingo Heesemann2, Felix Becker1, Adelheid Godt2, Detlef Diesing3, Walter Pfeiffer1; 1Fakultät für Physik, Universität Bielefeld, Germany; 2Fakultät für Chemie, Universität Bielefeld, Germany; 3Fakultät für Chemie, Universität Duisburg-Essen, Germany. ABSTRACT Gold nanoparticles on a metal-insulator-metal junction locally enhance the absorption of few cycle laser pulses. The locally heated electron gas leads to thermionic emission exceeding multiphoton emission and allows detection of single nanoparticles.

09.Wed.P3.48 Transient-grating Stark Spectroscopy 1 1 1 1 1 Anton Loukianov , Jie Pan , Jennifer P. Ogilvie , Daniel E. Wilcox ; Physics and Biophysics, University of Michigan, USA. WEDNESDAY ABSTRACT We describe a novel nonlinear spectroscopy that combines the high signal-to-noise of heterodyne-detected transient-grating spectroscopy with Stark spectroscopy, enabling sensitive detection of charge transfer kinetics. We demonstrate the method on the carotenoid fucoxanthin.

09.Wed.P3.49 High ﬂ ux table-top ultrafast soft X-ray source generated by high harmonic generation Nicolas Thiré1, Bruno E. Shmidt1, Sylvain Fourmeaux1, Samuel Beaulieu1, Vincent Cardin1, Matteo Negro2, Jean-Claude Kieffer1, Caterina Vozzi2, François Légaré1; 1INRS-EMT / ALLS, Canada; 2Istituto di Fotonica e Nanotecnologie, CNR, Italy. ABSTRACT Intense, few-cycle infrared laser pulses centered at 1.8 µm wavelength, coupled to a new gas cell design, are employed to drive high harmonic generation with high ﬂ ux down to the soft X-ray regime.

09.Wed.P3.50 Design and Implementation of a Flexible Beamline for fs Electron Diffraction Experiments Giulia Fulvia Mancini1; 1ICMP, EPFL, Switzerland. ABSTRACT We report the design and implementation of a table-top apparatus for Ultrafast Electron Diffraction in transmission and reﬂ ection geometry at 30 keV. From a light-electrons cross-correlation experiment the overall temporal resolution is estimated around 300 fs for bunches containing up to 105 electrons at 20 kHz repetition rate.

09.Wed.P3.51 4-fs pulses, single-shot, high dynamic and long temporal range self-referenced spectral interferometry measurement Thomas Oksenhendler1, Andrea Trabattoni2, Sunilkumar Anumula2, Giuseppe Sansone2, Gabriel Tempea3, Francesca Calegari2, Mauro Nisoli2; 1FASTLITE Ultrafast Sci Instrumentation, France; 2Department of Physics, Plitecnico di Milano, Italy; 3Femtolasers Produktions GmbH, Austria. ABSTRACT 4-fs, 1.9-mJ, pulses measurement with 40dB dynamic on +/- 500-fs temporal range was implemented by single-shot Self-Referenced Spectral Interferometry method. The experimental results agree well with pulse reconstruction from streaking with isolated attosecond pulses.

09.Wed.P3.52 High-Speed Carrier-Envelope Phase Control in a 10 kHz, mJ-Class Ampliﬁ er Fabian Lücking1, Vincent Crozatier2, Andreas Assion1; 1Femtolasers Produktions GmbH, Austria; 2Fastlite, France. ABSTRACT We present a fast spectrometer enabling the carrier-envelope phase measurement of every single shot emitted by a 10 kHz, mJ-class ampliﬁ er. Using a free parameter in the feed-forward stabilization technique, we demonstrate arbitrary phase control and closed-loop integrated phase noise on seed oscillator level (98 mrad, 100000 shots, 50 s).

09.Wed.P3.53 Fiber-Slab-Pumped OPCPA for XUV-Based Time-Resolved Photoelectron Spectroscopy at 500 kHz Repetition Rate Michele Puppin1, Yunpei Deng1, Oliver Prochnow2, Jan Matyschok2,3, Thomas Binhammer2, Uwe Morgner3, Martin Wolf1, Ralph Ernstorfer1; 1Physical Chemistry, Fritz-haber Institut, Germany; 2VENTEON Laser Technologies, Germany; 3Institute of Quantum Optics, Leibniz Universitaet Hannover, Germany. ABSTRACT A passive optically-synchronized OPCPA based on a combination of ﬁ ber and slab pump lasers is presented. We demonstrate 30 µJ, sub-20 fs, 780 nm pulses at 500 kHz repetition rate, suitable for high harmonic generation. 53 ▶ TECHNICAL SESSIONS

09.Wed.P3.54 Vector Pulse Shaped Ultrafast Plasmon Based on Response Functions Measured for Orthogonally Polarized Excitation Yuta Masaki1, Miyuki Kusaba1, Kazunori Toma1, Fumihiko Kannari1; 1Electronics and Electrical Engineering, Keio University, Japan. ABSTRACT For spatiotemporal vector pulse control of local plasmon at gold nanostructures, we measure plasmon response functions for orthogonally polarized ultrafast excitation. By shaping the vector pulse of excitation laser, we arbitrary shape plasmon vector pulses.

09.Wed.P3.55 Manipulation of optical fi eld emitted from autoionizing transition stimulated by isolated attosecond pulse Hiroki Mashiko1, Tomohiko Yamaguchi1,2, Katsuya Oguri1, Akira Suda2, Hideki Gotoh1; 1Optical Science Lab., NTT Basic Research Laboratories, Japan; 2Physics, Tokyo University of Science, Japan. ABSTRACT We temporally manipulated optical fi eld emitted from autoionizing transition stimulated by isolated attosecond pulse. The controlled optical fi eld has approximately 1-eV bandwidth, which corresponds to approximately 2 fs duration.

WEDNESDAY 09.Wed.P3.56 Single Quantum Emitter Spectroscopy with Visible Sub-10 fs Pulses Alexander Weigel1, Aleksandar Sebesta1, Philipp Kukura1; 1Physical and Theoretical Chemistry, University of Oxford, United Kingdom. ABSTRACT We present a novel white light source providing sub-10 fs visible pulses with MHz repetition rates and apply it in femtosecond pulse pair experiments on single quantum emitters.

09.Wed.P3.57 2 MHz tunable non collinear optical parametric ampliﬁ ers with pulse durations down to 6 fs Julien Nillon1,2, Olivier Cregut1, Christian Bressler2, Stefan Haacke1; 1Institut de Physique et Chimie des Matériaux de Strasbourg, University of Strasbourg - CNRS, France; 2European XFEL, Germany. ABSTRACT We present a 2 MHz non collinear optical parametric ampliﬁ er for high repetition rate time resolved X-ray or optical spectroscopy, with pulse durations down to 6,0 fs and energies in the 30 - 800 nJ range.

09.Wed.P3.58 Tilted Transmission Grisms for Pulse Compression with Dispersion Control Up to the Fourth Order Nicolas Forget1, Stéphanie Grabielle1, Pierre Tournois1; 1FASTLITE, France. ABSTRACT We demonstrate a grism compressor designed to compensate the second, third and fourth order dispersions of a 1.5m SF57 stretcher at 800nm.

09.Wed.P3.59 Towards oscillator driven strong-ﬁ eld experiments using high-energy modelocked thin-disk lasers Clara J. Saraceno1,2, Florian Emaury1, Cinia Schriber1, Andreas Diebold1, Matthias Golling1, Thomas Sudmeyer2, Ursula Keller1; 1ETH Zurich, Switzerland; 2University of Neuchatel, Switzerland. ABSTRACT We present latest pulse energy and average power scaling of modelocked thin-disk lasers. Efficient compression in a gas- filled Kagome-type hollow-core--PCF at high-average power is demonstrated, resulting in a unique high-repetition-rate source for strong- field experiments.

09.Wed.P3.60 Above-Millijoule Optical Waveforms Compressible to Sub-fs Using Induced-Phase Modulation in a Neon-Filled Hollow-Core Fiber Shaobo Fang1,2, Hong Ye1,3, Giovanni Cirmi1,2, Giulio Rossi1,3, Shih-Hsuan Chia1,3, Oliver D. Mücke1,2, Franz X. Kärtner1,4; 1Center for Free-Electron Laser Science, Germany; 2The Hamburg Center for Ultrafast Imaging, Germany; 3Physics Department, University of Hamburg, Germany; 4Department of Electrical Engineering and Computer Science and Research Laboratory of Electronics, Massachusetts Institute of Technology, USA. ABSTRACT We demonstrate 1.7-mJ optical waveforms based on induced-phase modulation for generating sub-femtosecond optical pulses. Using custom-designed double-chirped mirrors and a spatial light modulator, such optical waveforms will become a versatile tool for strong-ﬁ eld attoscience. 54 TECHNICAL SESSIONS ▶

Room A 17:15-19:00 09.Wed.E Time-resolved Imaging Presider: Marcos Dantus (Michigan State University, United States)

09.Wed.E.1 17:15 Invited Imaging Lattice Dynamics in Individual Nanocrystals Jesse N. Clark1,8, Loren Beitra1, Gang Xiong1, Andrew Higginbotham2, David Fritz3, Henrik Lemke3, Diling Zhu3, Matthieu Chollet3, Garth Williams3, Marc Messerschmidt3, Brian Abbey4, Ross Harder5, Alexander Korsunsky6,7, Justin Wark2, Ian Robinson1,7; 1London Centre for Nanotechnology, United Kingdom; 2Department of Physics, University of Oxford, United Kingdom; 3Linac Coherent Light Source, SLAC National Accelerator Laboratory, USA; 4Department of Physics, La Trobe University, Australia; 5 6 7 Advanced Photon Source, USA; Department of Engineering Science, University of Oxford, United Kingdom; Research Complex at WEDNESDAY Harwell, United Kingdom; 8Stanford PULSE Institute, Stanford University, USA. ABSTRACT We report imaging of coherent acoustic phonons on the picosecond time scale within a single nanocrystal using an X-ray free- electron laser. Our results allow unprecedented comparison with predictive models and observation of the vibrational modes.

09.Wed.E.2 17:45 Contributed Ultrafast Dynamics of Individual, Isolated Nanoparticles and Nanoplasmas in Intense Laser Fields Daniel Hickstein1, Franklin Dollar1, Jim A. Gaffney2, Mark E. Foord2, George M. Petrov3, Brett B. Palm4, Jennifer L. Ellis1, Chengyuan Ding1, Ellen Keister1, Stephen B. Libbey2, Jose L. Jimenez4, Henry Kapteyn1, Margaret Murnane1, Wei Xiong1; 1Department of Physics, JILA - University of Colorado and NIST, USA; 2Physics Division, Lawrence Livermore National Laboratory, USA; 3Plasma Physics Division, Naval Research Laboratory, USA; 4Department of Chemistry, University of Colorado and CIRES, USA. ABSTRACT We combine an aerodynamic lens with a velocity-map-imaging spectrometer to make the first measurements of shock wave generation and ultrafast dynamics in individual nanoplasmas, conﬁ rming a decade of theoretical predictions.

09.Wed.E.3 18:00 Contributed Visualization of ultrafast electron dynamics using time-resolved photoemission electron microscopy Keiki Fukumoto1,2, Yuki Yamada1,2, Takashi Matsuki1,2, Ken Onda1,3, Tomohiro Noguchi1, Raisei Mizokuchi1, Shunri Oda1, Shin- ya Koshihara1,2; 1Tokyo Institute of Technology, Japan; 2JST-CREST, Japan; 3JST-PRESTO, Japan. ABSTRACT We constructed a TR-PEEM which can directly image the photo-generated electron dynamics in semiconductor on nm and fs scales. Carrier transport properties relating to device performance, carrier lifetime, drift velocity and mobility, are investigated.

09.Wed.E.4 18:15 Contributed Real space and real time observation of plasmon wavepacket dynamics in single gold nanorod Yoshio Nishiyama1, Tetsuya Narushima1, Kohei Imura2, Hiromi Okamoto1; 1Photo-Molecular Science, Institute for Molecular Science, Japan; 2School of Advanced Science and Engineering, Waseda University, Japan. ABSTRACT We applied ultrafast time-resolved near-field optical microscopy to spatio-temporal observation of plasmon dynamics in a gold nanorod. We found prominent changes of transient near-ﬁ eld images as time evolves, indicating coherent excitation of multiple plasmon modes.

09.Wed.E.5 18:30 Contributed Visualization of Charge Carrier Motion in Semiconductor Nanowires with Ultrafast Pump-Probe Microscopy Michelle Gabriel1, Erik Grumstrup1, Justin Kirschbrown1, Christopher Pinion1, Joseph Christesen1, David Zigler1, Emma Cating1, James Cahoon1, John Papanikolas1; 1Univ of North Carolina at Chapel Hill, USA. ABSTRACT Femtosecond pump-probe microscopy is used to directly visualize the diffusion of photogenerated charge carriers in undoped silicon nanowires, as well as charge separation in a nanowire encoded with an axial p-type/intrinsic/n-type (p-i-n) junction.

09.Wed.E.6 18:45 Contributed Single-nanoparticle Phase Transitions Visualized by Ultrafast Electron Microscopy Renske van der Veen1,2, Antoine Tissot3, Andreas Hauser3, Oh-Hoon Kwon1, Ahmed Zewail1; 1California Institute Of Technology, USA; 2Deutsches Elektronen Synchrotron (DESY), Germany; 3University of Geneva, Switzerland. ABSTRACT We use ultrafast electron microscopy (UEM) to visualize the spin-crossover dynamics of single, isolated metal-organic framework nanocrystals. The approach reported here has potential applications in other nanosystems undergoing (bio)chemical transformations. 55 ▶ TECHNICAL SESSIONS

Thursday, July 10

Room A 08:30-10:15 10.Thu.A Strong THz Field Phenomena in Solids Presider: Koichiro Tanaka (Kyoto University, Japan)

10.Thu.A.1 08:30 Invited Higgs Mode and Terahertz Nonlinear Optics in Superconductors Ryo Shimano1, Ryusuke Matsunaga1, Yuki Hamada1, Arata Sugioka1, Hiroyuki Fujita1, Kazumasa Makise2, Yoshinori Uzawa3, Hirotaka Terai1, Zhen Wang2, Naoto Tsuji1, Hideo Aoki1; 1Department of Physics, The University of Tokyo, Japan; 2National Institute of Information and Communication Technology, Japan; 3National Astronomical Observatory of Japan, Japan. ABSTRACT By using intense terahertz pulses, we investigated the ultrafast coherent light-matter interaction of s-wave superconductors. We observed the Higgs amplitude mode and demonstrated the coherent terahertz nonlinear transient phenomena in superconductors.

10.Thu.A.2 09:00 Contributed Observation of Floquet-Bloch states on the surface of a topological insulator Yihua Wang1,2, Hadar Steinberg2, Pablo Jarillo-Herrero2, Nuh Gedik2; 1Physics, Stanford University, USA; 2Physics, MIT, USA. ABSTRACT Photon dressed surface bands of topological insulators exhibit band gaps at avoided crossings. Circularly polarized photons induce an additional gap at the Dirac point, which is a signature of broken time-reversal symmetry on the surface. THURSDAY

10.Thu.A.3 09:15 Invited Phase-locked Multi-THz High-Harmonic Generation by Dynamical Bloch Oscillations in Bulk Semiconductors Matthias Hohenleutner1, Olaf Schubert1, Fabian Langer1, Benedikt Urbanek1, Christoph Lange1, Ulrich Huttner2, Daniel Golde2, Torsten Meier3, Mackillo Kira2, Stephan W. Koch2, Rupert Huber1; 1Department of Physics, University of Regensburg, Germany; 2Department of Physics, University of Marburg, Germany; 3Department of Physics, University of Paderborn, Germany. ABSTRACT Ultra-intense and CEP-stable waveforms in the multi-THz range control dynamical Bloch oscillations and interband polarization in bulk GaSe, leading to the emission of all-coherent high-order harmonics covering 12.7 optical octaves from THz to VIS regimes.

10.Thu.A.4 09:45 Contributed

Field-induced dynamics of correlated electrons in LiH and NaBH4 Vincent Juvé1, Marcel Holtz1, Flavio Zamponi1, Michael Woerner1, Thomas Elsaesser1, Andreas Borgschulte2; 1Max-Born- Institut Berlin, Germany; 2Laboratory for Hydrogen and Energy (EMPA), Swiss Federal Laboratories for Materials Testing and Research, Switzerland. ABSTRACT Femtosecond x-ray powder diffraction maps electron density in response to a strong electric ﬁ eld. In LiH, electron correlations lead to - + an electron transfer from Li to H while NaBH4 shows a transfer from BH4 to Na .

10.Thu.A.5 10:00 Contributed

Ultrafast Insulator-Metal Transition in VO2 Driven by Intense Multi-THz Pulses Alexander Grupp1, Bernhard Mayer1, Christian Schmidt1, Jannis Oelmann1, Robert E. Marvel2, Richard F. Haglund2, Alfred Leitenstorfer1, Alexej Pashkin1; 1Department of Physics and Center for Applied Photonics, University of Konstanz, Germany; 2Department of Physics and Astronomy, Vanderbilt University, USA.

ABSTRACT We demonstrate a non-thermal metallization of VO2 induced by a non-resonant excitation at frequencies around 25 THz. An ultrafast switching time of 80 fs comprises only two cycles of the driving multi-THz ﬁ eld.

56 TECHNICAL SESSIONS ▶

Room A 10:45-12:30 Room B 10:45-12:30

10.Thu.B Novel Ultrafast 10.Thu.C Microscopy and Spectroscopy in Solids Dielectrics Presider: Kazutaka Nakamura Presider: Jesse Clark (Tokyo Institute of Technology, (London Centre for Nanotechnology, Japan) United Kingdom)

10.Thu.B.1 10:45 Contributed 10.Thu.C.1 10:45 Contributed Magnetic Circular Dichroism probed using Two-dimensional molecular imaging High Harmonics by coherent Raman spectroscopy with Patrick Grychtol1, Ofer Kﬁ r2, Ronny Knut1,3, Emrah Turgut1, quadrature phase modulation 1 1 1 Dmitriy Zusin , Dimitar Popmintchev , Tenio Popmintchev , Takayuki Suzuki1, Yuki Obara1, Kana Kiman1, Kazuhiko 3 3 2,4 Hans Nembach , Justin M. Shaw , Avner Fleischer , Henry Misawa1; 1Department of Applied Physics, Tokyo Univ of 1 1 2 1 Kapteyn , Margaret Murnane , Oren Cohen ; Department Agriculture and Technology, Japan. 2 of Physics and JILA, University of Colorado, USA; Solid ABSTRACT We improved phase sensitive method for CARS State Institute and Physics Department, Technion, Israel;

spectroscopy. The improvement enables us to construct CARS spectra THURSDAY 3 Electromagnetics Division, National Institute of Standards only from 4 raw spectra. We successfully obtain two-dimensional image 4 and Technology, USA; Department of Physics and Optical of small anesthetic molecules without label molecules. Engineering, Ort Braude College, Israel. ABSTRACT We demonstrate the fi rst generation and phase matching of circularly-polarized high harmonics, which are bright enough for 10.Thu.C.2 11:00 Contributed magnetic circular dichroism measurements at the M absorption edges Simultaneous Selective Two-Photon of the magnetic materials Fe, Co and Ni. Microscopy Using MHz Rate Pulse Shaping and Quadrature Detection of the 10.Thu.B.2 11:00 Contributed Time-Multiplexed Signal Towards the Absolute Timing of Photoemission Ilyas Saytashev1, Bingwei Xu3, Marshall T. Bremer2, Marcos 1,2 1 from Condensed Matter Systems Dantus ; Department of Chemistry, Michigan State University, 2 1,2 1,2 USA; Department of Physics and Astronomy, Michigan State Marcus Ossiander , Johann Riemensberger , Martin University, USA; 3Biophotonic Solutions Inc., USA. Schäffer1,2, Michael Gerl1,2, Agustin Schiffrin3,4, Johannes V. Barth1, Ferenc Krausz2,5, Reinhard Kienberger1,2, Peter ABSTRACT We demonstrate a method for simultaneous fast selective two-photon excited fl uorescence (TPEF) microscopy imaging Feulner1, Stefan Neppl1,6; 1Physik-Department, Technische of two different fl uorophores using quadrature detection of the signal Universität München, Germany; 2LAP, Max-Planck-Institut für from a single PMT detector. Quantenoptik, Germany; 3Quantum Matter Institute, University of British Columbia, Canada; 4Department of Physics and Astronomy, University of British Columbia, Canada; 5Fakultät 10.Thu.C.3 11:15 Invited für Physik, Ludwig-Maximilians-Universität München, Germany; 6Ultrafast X-Ray Science Laboratory, Lawrence Infrared Pump-Probe Imaging and Berkeley National Lab, USA. Spectroscopy with 10nm Resolution 1 2 2 ABSTRACT We introduce a viable scheme for measuring the Sergiu Amarie , Martin Wagner , Michael Goldfla , Zhe absolute duration of photoemission from solids. It employs an atomic Fei2, Wenzhong Bao4,5, Aleksandr Rodin3, Michael Fogler2, chronograph on the surface during attosecond streaking spectroscopy. Antonio Castro Neto3, Fritz Keilmann6, Dimitri Basov2; First experimental results on a tungsten(110) surface are presented. 1Neaspec GmbH, Germany; 2Department of Physics, University of California, USA; 3Department of Physics, Boston University, USA; 4Materials Research Science and Engineering Center, 10.Thu.B.3 11:15 Contributed University of Maryland, USA; 5Department of Physics and Delayed Core-Level Photoemission from Astronomy, University of California, USA; 6Department of Physics, Ludwig-Maximilians-University and Center for the van der Waals Crystal WSe2 Nanoscience, Germany. Fabian Merschjohann1, Sergej Neb1, Peter Bartz1, Matthias Hensen1, Christian Strüber1, Sebastian Fiechter2, Norbert ABSTRACT We introduce pump−probe sub-diffraction infrared imaging and spectroscopy with 100fs temporal and 10nm spatial Müller1, Walter Pfeiffer1, Ulrich Heinzmann1; 1Fakultät für resolution. On graphene single-layers, we demonstrate time-resolved Physik, Universität Bielefeld, Germany; 2Institut für Solare access to local optical conductivity at technologically relevant mid- Brennstoffe, Helmholtz Zentrum Berlin, Germany. infrared frequencies ABSTRACT Attosecond time-resolved XUV streaking experiments are reported for cleaved WSe2 surfaces. The photoemission from Se 3d and W 4f core levels occurs delayed by 50 attoseconds with respect to the valence band emission. 57 ▶ TECHNICAL SESSIONS

10.Thu.B.4 11:30 Contributed 10.Thu.C.4 11:45 Contributed Attosecond Pump-Probe Measurement of Simultaneous Spatial and Temporal Focusing an Auger Decay of Femtosecond Laser Pulses for Directly Antoine Moulet1, Julien B. Bertrand1, Arohi Jain2, Manish Writing Optical Waveguides in Garg1, Tran Trung Luu1, Alexander Guggenmos1,2, Stefan Pr3+ doped ZBLAN Glass 3,4 1,2 1 1 Pabst , Ferenc Krausz , Eleftherios Goulielmakis ; Max- Yusuke Yamanaka1, Kenichi Hirosawa1, Fumihiko Kannari1; 2 Planck-Institut für Quantenoptik, Germany; Physics, Ludwig- 1Keio University, Japan. Maximilians-Universität, Germany; 3Center for Free-Electron ABSTRACT We present characteristics of optical waveguides in Laser Science, DESY, Germany; 4Physics, University of Pr:ZBLAN glass using simultaneous spatial and temporal focusing Hamburg, Germany. (SSTF). SSTF realizes smaller laser-modified region with a long ABSTRACT We characterize the Auger decay of core-shell working distance, which brings flexibility and better quality in excitations in Krypton atoms in an all-photonic fashion, using a novel waveguide fabrication. attosecond EUV pump - attosecond optical probe scheme. An intuitive model, where the optical fi eld acts as a temporal amplitude and phase gate on the EUV excited dipole, is used to retrieve the Auger core-hole 10.Thu.C.5 12:00 Contributed decay time. Non-instantaneous polarization decay in dielectric media 10.Thu.B.5 11:45 Contributed Michael Hofman1, Carsten Bree1, Matthias Hoffmann2, Ayhan 2 2 2,3 2,3 Controlling the motion of strong-fi eld, Demircan , Tamas Nagy , Detlef Ristau , Uwe Morgner , 4 4 4 few-cycle photoemitted electrons in Simon Birkholz , Susanta K. Das , Martin Bock , Rüdiger Grunwald4, Janne Hyyti5, Thomas Elsaesser4, Gunter the near-fi eld of a sharp metal tip 4,5 1 1,2 1,2 1,2 Steinmeyer ; Weierstrass-Institut für Angewandte Analysis Petra Gross , Björn Piglosiewicz , Slawa Schmidt , 2 1,2 1,2 1,2 und Stochastik, Germany; Laserzentrum Hannover, Germany; THURSDAY Doo Jae Park , Jan Vogelsang , Jörg Robin , Cristian 3Leibniz-Universität Hannover, Germany; 4Max Born Institute, 3 3 3 Manzoni , Paolo Farinello , Giulio Cerullo , Christoph Germany; 5Optoelectronics Research Centre, Finland. Lienau1,2; 1Institut für Physik, Carl von Ossietzky Universität, 2 ABSTRACT We demonstrate experimental evidence for non- Germany; Center of Interface Science, Carl von Ossietzky instantaneous polarization decay in dielectrics. The few-femtosecond 3 Universität, Germany; Dipartimento di Fisica, Politecnico di relaxation times agree favorable with solutions of the time-dependent Milano, Italy. Schrödinger equation and relate to resonances of the quantum ABSTRACT We report on the experimental observation of mechanical dipole. pronounced carrier-envelope-phase effects on strong-field photoemission of electrons from nanometric gold tips and present a new way to steer and control the motion of electrons around metallic 10.Thu.C.6 12:15 Contributed nanoparticles. Investigation of Laser-Induced Currents in Large-Band-Gap Dielectrics 1,2 1 10.Thu.B.6 12:00 Contributed Sabine Keiber , Tim Paasch-Colberg , Alexander Schwarz1,2, Olga Razskazovskaya1, Elena Fedulova1, Özge Injection of CEP-controllable Current in 3 1 1 Wide-bandgap Semiconductors: Sağlam , Clemens Jakubeit , Shawn Sederberg , Péter Dombi1, Nicholas Karpowicz1, Ferenc Krausz1,2; 1Max- Effects of the Screening Field 2 Planck-Institut für Quantenoptik, Germany; Fakultät für 1 1 1 Stanislav Kruchinin , Tim Paasch-Colberg , Nicholas Karpowicz , Physik, Ludwig-Maximilians-Universität, Germany; 3Physik- 1,2 1,3 1,3 Agustin Schiffrin , Vladislav S. Yakovlev , Ferenc Krausz ; Department, Technische Universitat München, Germany. 1 Laboratory for Attosecond Physics, Max Planck Institute of ABSTRACT Applying few-cycle laser pulses to dielectrics increases 2 Quantum Optics, Germany; Max Planck - UBC Centre for their ac-polarizability, allowing for switching currents at the frequency Quantum Materials University of British Columbia, Canada; of light. We report on the dependence of these ultrafast currents on 3 Ludwig Maximilian University of Munich, Germany. material band gap and sample geometry. ABSTRACT A multiphoton mechanism of ultrafast current injection and control in GaN is studied. Analysis has shown that screening fi eld of free charge carriers determines the fi eld amplitude scaling law and strongly affects the charge-balancing phase.

10.Thu.B.7 12:15 Contributed Coherent control over two-dimensional lattice vibrational trajectories in α-quartz using polarization pulse shaping Masaaki Sato1, Takuya Higuchi2,3, Makoto Kuwata- Gonokami3,4, Kazuhiko Misawa1,5; 1Department of Applied Physics, Tokyo University of Agriculture and Technology, Japan; 2Department of Applied Physics, The University of 58 TECHNICAL SESSIONS ▶

Tokyo, Japan; 3Department of Physics, The University of Tokyo, Japan; 4Photon Science Center, The University of Tokyo, Japan; 5Interdisciplinary Research Unit in Photon-nano Science, Tokyo University of Agriculture and Technology, Japan. ABSTRACT We applied polarization pulse shaping to control the trajectory of two-dimensional vibrational motion in α-quartz. Polarization twisted pulses were used to impart peudorotational motion of the degenerate E-symmetry optical phonon mode selectively through impulsive stimulated Raman scattering.

Room A 14:00-15:45 10.Thu.D Excited State Dynamics Presider: Regina de Vivie-Riedle (Ludwig-Maximillians-Universität Munchen, Germany)

10.Thu.D.1 14:00 Invited

Ultrafast Intersystem Crossing in SO2 and Nucleobases 1 1 1 1 1

Sebastian Mai , Martin Richter , Philipp Marquetand , Leticia González ; Institute of Theoretical Chemistry, University of THURSDAY Vienna, Austria.

ABSTRACT Mixed quantum-classical dynamics simulations show that intersystem crossing between singlet and triplet states in SO2 and in nucleobases takes place on an ultrafast time decay (few 100 fs), directly competing with internal conversion.

10.Thu.D.2 14:30 Contributed Distinctive Spectral Features of Exciton and Excimer States in the Ultrafast Electronic Deactivation of the Adenine Dinucleotide Mayra C. Stuhldreier1, Katharina Röttger1, Friedrich Temps1; 1Christian-Albrechts Universität zu Kiel, Germany. ABSTRACT We report the observation of distinctive spectro-temporal signatures of delocalized exciton vs. relaxed, weakly bound excimer states in the ultrafast electronic deactivation after UV photoexcitation of the adenine dinucleotide followed by transient absorption spectroscopy.

10.Thu.D.3 14:45 Contributed Quantum Dynamics of Molecular Reactions Directed by Explicit Solvent Environment Sebastian Thallmair1, Julius Zauleck1, Regina de Vivie-Riedle1; 1Ludwig-Maximilians-Universität, Germany. ABSTRACT We present the ﬁ rst method that combines molecular quantum dynamics of the solute with classical molecular dynamics of the solvent. Its mechanical impact on the ultrafast internal motions is decisive for the reaction outcome.

10.Thu.D.4 15:00 Contributed Photoinduced charge transfer occurs naturally in DNA Dominik B. Bucher1,2, Bert M. Pilles1, Thomas Carell2, Wolfgang Zinth1; 1BioMolecular Optics and Center for Integrated Protein Science, Ludwig-Maximilians-Universität München, Germany; 2Center for Integrated Protein Science at the Department of Chemistry, Ludwig-Maximilians-Universität München, Germany. ABSTRACT We show by femtosecond IR spectroscopy that excited states in oligonucleotides decay with high yields by charge transfer to delocalized charged radicals. For the 6-4 lesion, charge transfer protects the DNA from Dewar formation.

10.Thu.D.5 15:15 Contributed Probing Ultrafast Structural Dynamics of Photoactive Yellow Protein with Femtosecond Time-Domain Raman Spectroscopy Hikaru Kuramochi1, Satoshi Takeuchi1,2, Kento Yonezawa3, Hironari Kamikubo3, Mikio Kataoka3, Tahei Tahara1,2; 1Molecular Spectroscopy Laboratory, RIKEN, Japan; 2Ultrafast Spectroscopy Research Team, RIKEN Center for Advanced Photonics (RAP), Japan; 3Graduate School of Materials Science, Nara Institute of Science and Technology, Japan. ABSTRACT Ultrafast dynamics of photoactive yellow protein was investigated by time-resolved impulsive stimulated-Raman spectroscopy. Time-Domain vibrational data revealed rapid change of the hydrogen-bonding structure in the excited state and vibrational structure of the ﬁ rst ground-state intermediate.

59 ▶ TECHNICAL SESSIONS

10.Thu.D.6 15:30 Contributed Towards Direct Measurement of Ultrafast Vibrational Energy Transfer in Proteins Henrike Müller-Werkmeister1,2, Martin Essig1, Patrick Durkin3, Nediljko Budisa3, Jens Bredenbeck1; 1Institute for Biophysics, University of Frankfurt, Germany; 2Chemistry, University of Toronto, Canada; 3Chemistry, Berlin Institute of Technology, Germany. ABSTRACT Vibrational energy transfer (VET) within a molecule can be investigated in great detail by ultrafast IR spectroscopy. We report on progress towards mapping of VET pathways in proteins using unnatural amino acids as site-speciﬁ c probes. THURSDAY

60 TECHNICAL SESSIONS ▶

Friday, July 11

Room A 08:30-10:15 11.Fri.A Vibrational Dynamics Presider: Tahei Tahara (RIKEN, Japan)

11.Fri.A.1 08:30 Contributed Hydrogen Bond Enhancement of Fermi Resonances Explored with Ultrafast IR Two-Colour Pump-Probe and 2D-IR Spectroscopy Christian Greve1, Rene Costard1, Henk Fidder1, Erik T.J. Nibbering1; 1Max Born Institut fuer Nichtlineare Optik und Kurzzeitspektroskopie, Germany. ABSTRACT Ultrafast polarisation-resolved 2D-IR mapping the fundamental and first overtone N-H stretching manifolds, and two-colour IR pump-probe experiments following transient population dynamics characterize a key role of a Fermi resonance with the NH2-bending in aniline- dimethylsulfoxide complexes.

11.Fri.A.2 08:45 Contributed Site-Addressable Polymer Dynamics Probed with 2D-IR Laura Kiefer1, John T. King1, Kevin J. Kubarych1; 1Chemistry, University of Michigan, USA. ABSTRACT A polymer consisting of transition metal carbonyl sites enables dynamical readout of ultrafast structural fluctuations in dilute, concentrated, and thin ﬁ lm conditions. 2D-IR spectroscopy and coarse grained simulations reveal distinct dynamics of the ends. FRIDAY 11.Fri.A.3 09:00 Contributed Room-Temperature studies of Electronic Coherences in Two-Dimensional Nanostructures Gregory D. Scholes1, Elsa Cassette1, Ryan Pensack1, Benoit Mahler1; 1University of Toronto, Canada. ABSTRACT We use two-dimensional electronic spectroscopy to study the lineshapes and linewidths of excitons in colloidal nanoplatelets at room temperature and the coherences induced by the superposition of the two ﬁ rst excitonic states.

11.Fri.A.4 09:15 Contributed Vibrational Coherence Reveals the Role of Dark Multiexciton States in Ultrafast Singlet Exciton Fission Akshay Rao1, Artem Bakulin2, Dassia Egorova4, Alex Chin1, Donatas Zigmantas3, Sarah Morgan1; 1University of Cambridge, United Kingdom; 2FOM Institute, Netherlands; 3Lund University, Sweden; 4Christian-Albrechts-Universität zu Kiel, Germany. ABSTRACT We use 2D electronic photon-echo spectroscopy to study ultrafast singlet exciton ﬁ ssion in pentacene. Our observations and analysis of vibronic coherences provide insight to the role played by dark multiexcitonic states in mediating ﬁ ssion.

11.Fri.A.5 09:30 Contributed Controlling Excitations of Coupled Vibrations by Shaped Mid-Infrared Pulses Jumpei Tayama1, Naoki Wakabayashi1, Satoshi Ashihara1; 1Tokyo Univ of Agriculture and Technology, Japan. ABSTRACT Mid-infrared pulse shaping was utilized for controlling excitations of coupled vibrations in metal di-carbonyls. Excitation into the combination state was maximized by simultaneous controls over vibrational ladder climbing and quantum mechanical multi-path interference.

11.Fri.A.6 09:45 Contributed Snapshots of sub-picosecond dynamics in heme-proteins captured by Femtosecond Stimulated Raman Scattering Tullio Scopigno1, Carino Ferrante1, Emanuele Pontecorvo1, Giovanni Batignani1; 1Universita degli Studi di Roma La Sapienza, Italy. ABSTRACT The reaction pathway in photoexcited hemeproteins (ligand dissociation, energy redistribution and structural dynamics) has been unraveled by Femtosecond Stimulated Raman Scattering. The possible existence of short living intermediates as opposed to vibrational relaxation is discussed.

61 ▶ TECHNICAL SESSIONS

11.Fri.A.7 10:00 Contributed Observation of the Dark State in Ruthenium Complexes Using Femtosecond Infrared Vibrational Spectroscopy Ken Onda1,2, Tatsuhiko Mukuta1, Sei’ichi Tanaka1, Kei Murata3, Akiko Inagaki2,4; 1Graduate School of Science and Engineering, Tokyo Institute of Technology, Japan; 2PRESTO, Japan Science and Technology Agency, Japan; 3Chemical Resources Laboratory, Tokyo Institute of Technology, Japan; 4Graduate School of Science and Engineering, Tokyo Metropolitan University, Japan. ABSTRACT We comprehensively studied the excited states of prototypical ruthenium complexes using time-resolved infrared vibrational spectroscopy and found a band assigned to the dark 3MC (metal centered) state, which plays an important role for their photofunctions.

Room A 10:45-12:30 11.Fri.B XFEL and High-order Harmonic Spectroscopy Presider: Tomoya Okino (RIKEN, Japan)

11.Fri.B.1 10:45 Contributed Disentangling structural and dynamical effects via multidimensional high harmonic spectroscopy Barry D. Bruner1, Hadas Soifer1, Matteo Negro3, Michele Devetta3, Davide Facciala2, Caterina Vozzi3, Salvatore Stagira2, Sandro De Silvestri2, Nirit Dudovich1; 1Physics of Complex Systems, Weizmann Institute of Science, Israel; 2Dipartimento di Fisica, Politecnico di Milano, Italy; 3Instituto di Fotonica e Nanotecnologie, CNR, Italy. ABSTRACT Extending the dimensionality of high harmonic generation (HHG) measurements has the potential to reconstruct structural features in molecules and resolve multielectron dynamics on attosecond time scales. We demonstrate that structural and dynamical effects in molecules can be unambiguously distinguished using multidimensional HHG techniques.

11.Fri.B.2 11:00 Contributed High-order harmonic light source at megahertz for FRIDAY double photoemission spectroscopy of correlated electrons Cheng-Tien Chiang1,2, Andreas Trützschler1,2, Michael Huth1, Frank O. Schumann1, Jürgen Kirschner1,2, Wolf Widdra2,1; 1Max Planck Institute of Microstructure Physics, Germany; 2Institute of Physics, Martin-Luther-Universitaet Halle-Wittenberg, Germany. ABSTRACT We develop high-order harmonic generation at repetition rates up to 1 MHz using an ytterbium-ﬁ ber laser and demonstrate the ﬁ rst laboratory double photoemission experiments with high-order harmonics to study strongly correlated materials.

11.Fri.B.3 11:15 Contributed Probing xenon electronic structure by two-color driven high-order harmonic generation Matteo Negro1, Davide Faccialà2, Barry D. Bruner3, Michele Devetta1, Sandro De Silvestri2, Nirit Dudovich3, Stefan Pabst4, Robin Santra4,5, Hadas Soifer3, Salvatore Stagira2, Caterina Vozzi1; 1Institute for Photonics and Nanotechnologies, CNR, Italy; 2Physics Department, Politecnico di Milano, Italy; 3Department of Physics of Complex Systems, Weizmann Institute of Science, Israel; 4Center for Free-Electron Laser Science, DESY, Germany; 5Department of Physics, University of Hamburg, Germany. ABSTRACT We studied the two-color HHG emission from xenon in the giant resonance spectral region. We found a substantial departure from the behavior expected for the single-active-electron picture which could be ascribed to electron correlation effects.

11.Fri.B.4 11:30 Contributed Attosecond control of electron emission from atoms and the relative phase of even and odd harmonics in an Attosecond Pulse Train Guillaume M. Laurent1,2, Wei Cao1, Itzik Ben-Itzhak1, C. Lew Cocke1; 1James R. Macdonald Laboratory, Physics Department, Kansas State University, USA; 2Research Laboratory of Electronics, Massachusetts Institute of Technology, USA. ABSTRACT We demonstrate that electron emission from atoms can be controlled on an attosecond time scale, and that such emission provides information on the phase of consecutive odd and even harmonics in the attosecond pulse train.

11.Fri.B.5 11:45 Contributed Attosecond Tunneling Interferometry Oren Pedatzur1, Gal Orenstein1, Hadas Soifer1, Barry D. Bruner1, Nirit Dudovich1; 1Weizmann Institute of Science, Israel. ABSTRACT By applying a weak perturbation to HHG we modulate the tunneling barrier in subcycle timescale. This gives rise to nontrivial temporal interference between consecutive attosecond bursts. The extracted interference patterns reveal nonadiabatic tunneling dynamics within the 160 as 62 ionization window. TECHNICAL SESSIONS ▶

11.Fri.B.6 12:00 Invited Femtosecond Time-Resolved X-ray-Induced Isomerization Philip H. Bucksbaum1, Chelsea Liekhus-Schmaltz1, Vladimir Petrovic1, Ian Tenney1; 1PULSE Institute, Stanford University, USA. ABSTRACT We investigated rapid proton migration in acetylene induced by 10 fs 400 eV x-rays, and probed with a second delayed x-ray pulse. Dynamics are revealed through delay-dependent fragmentation momenta. FRIDAY

63 ▶ AUTHORS’ INDEX

Bargheer, Matias ·························· 08.Tue.P2.36 Brixius, Kristina ······························· 07.Mon.C.2 Authors’ Index Barth, Johannes V. ··························· 10.Thu.B.2 Brixner, Tobias ································ 07.Mon.B.3 Barton, Robert A. ······························ 08.Tue.E.2 Brixner, Tobias ······························ 07.Mon.P1.1 Bromberger, Hubertus ····················· 07.Mon.D.4 AAbbey, Brian ································· 09.Wed.E.1 Bartz, Peter ······································ 10.Thu.B.3 Bromberger, Hubertus ·················· 08.Tue.P2.48 Abdellah, Mohamed ························· 08.Tue.E.1 Basov, Dimitri ·································· 10.Thu.C.3 Brooks, Charles L. ··························· 07.Mon.E.3 Abe, Kenta ······································· 08.Tue.C.7 Batignani, Giovanni ···························· 11.Fri.A.6 Bruner, Barry D. ································· 11.Fri.B.1 Abela, Rafael ·································· 09.Wed.D.1 Batista, Victor S. ·························· 09.Wed.P3.16 Bruner, Barry D. ································· 11.Fri.B.3 Abramavicius, Darius ························ 08.Tue.C.1 Baudisch, Matthias ························· 09.Wed.C.3 Bruner, Barry D. ································· 11.Fri.B.5 Adachi, Shunsuke ···························· 08.Tue.A.4 Baum, Peter ····································· 08.Tue.D.4 Bucher, Dominik B. ························· 10.Thu.D.4 Ahmed, Musa ····························· 09.Wed.P3.14 Baum, Peter ···································· 09.Wed.C.1 Bucksbaum, Philip H. ···················· 09.Wed.P3.8 Aikawa, Kyoko ································ 07.Mon.E.6 Baum, Peter ································ 09.Wed.P3.45 Bucksbaum, Philip H. ························· 11.Fri.B.6 Akagi, Hiroshi ······························· 09.Wed.P3.9 Bayer, Manfred ······························· 07.Mon.C.3 Buckup, Tiago ·································· 08.Tue.C.3 Akimov, Ilya ···································· 07.Mon.C.3 Bazan, Guillermo C. ························· 07.Mon.C.7 Buckup, Tiago ·································· 08.Tue.E.6 Ali, Akbar S. ································· 08.Tue.P2.54 Beaud, Paul ···································· 07.Mon.D.5 Budisa, Nediljko ······························ 10.Thu.D.6 Alisauskas, Skirmantas ··················· 07.Mon.A.3 Beaud, Paul ···································· 07.Mon.D.6 Bühler, Johannes ···························· 09.Wed.B.1 Alisauskas, Skirmantas ·················· 08.Tue.P2.7 Beaulieu, Samuel ···························· 07.Mon.B.2 Burgess, Jacob ································ 08.Tue.B.6 Alisauskas, Skirmantas ················ 08.Tue.P2.57 Beaulieu, Samuel ························ 09.Wed.P3.49 Busby, Erik ······································· 08.Tue.E.2 Almand-Hunter, Andrew ·················· 07.Mon.C.1 Becker, Andreas ······························ 07.Mon.A.2 Butkus, Vytautas ······························ 08.Tue.C.1 Alnaser, Ali ······································ 07.Mon.B.4 Becker, Felix ······························· 09.Wed.P3.47 Cacho, Cephise ··························· 07.Mon.P1.35 Alonso, Benjamin ························· 08.Tue.P2.60 Beernink, Molly B. ······················· 07.Mon.P1.18 Cacho, Cephise ···························· 08.Tue.P2.48 Amarie, Sergiu ································· 10.Thu.C.3 Beitra, Loren ··································· 09.Wed.E.1 Cahen, David ··································· 08.Tue.E.3 Amit, Yorai ·································· 09.Wed.P3.28 Belshaw, Louise ······························· 08.Tue.A.3 Cahoon, James ······························· 09.Wed.E.5 Ando, Toshiaki ····························· 07.Mon.P1.10 Benabid, Fetah ································· 08.Tue.D.7 Calegari, Francesca ························· 08.Tue.A.2 Andriuskaitis, Giedrius ···················· 07.Mon.A.4 Ben-Itzhak, Itzik ································· 11.Fri.B.4 Calegari, Francesca ························· 08.Tue.A.3 Anumula, Sunilkumar ······················· 08.Tue.A.3 Berggren, Karl ·································· 08.Tue.B.3 Calegari, Francesca ····················· 08.Tue.P2.52 Anumula, Sunilkumar ··················· 08.Tue.P2.52 Bergues, Boris ································ 07.Mon.B.4 Calegari, Francesca ···················· 09.Wed.P3.51 Anumula, Sunilkumar ·················· 09.Wed.P3.51 Bertrand, Julien B. ··························· 10.Thu.B.4 Calendron, Anne-Laure ··············· 07.Mon.P1.58 Aoki, Hideo ······································ 10.Thu.A.1 Bertsch, George F. ··························· 07.Mon.C.5 Callegari, Carlo ····························· 09.Wed.P3.5 Aoyama, Makoto ························· 07.Mon.P1.50 Beyer, Andreas ································ 07.Mon.C.2 Biagioni, Paolo ····························· 08.Tue.P2.45 Campi, Filippo ······························· 09.Wed.P3.2 Araki, Kotaro ······························· 09.Wed.P3.29 Biegert, Jens ·································· 09.Wed.C.3 Candeo, Alessia ··························· 08.Tue.P2.58 Arbeiter, Mathias ··························· 09.Wed.P3.2 Biggs, Jason D. ··························· 09.Wed.P3.22 Cankaya, Huseyin ······················· 07.Mon.P1.58 Ardana, Fernando ···························· 09.Wed.B.2 Binhammer, Thomas ··················· 09.Wed.P3.53 Cantaluppi, Alice ························· 07.Mon.P1.48 Ardana, Fernando ························ 09.Wed.P3.35 Birkholz, Simon ································ 10.Thu.C.5 Cao, Wei ············································ 11.Fri.B.4 Arissian, Ladan ································ 08.Tue.D.3 Bisht, Prem B. ······························ 08.Tue.P2.54 Caplins, Benjamin ······················· 07.Mon.P1.22 Arthur, Evan J. ································· 07.Mon.E.3 Bisson, Éric ····································· 07.Mon.B.2 Capone, Massimo ······················· 07.Mon.P1.33 Ashida, Masaaki ·························· 08.Tue.P2.47 Bluhm, Hendrik ··························· 09.Wed.P3.14 Cardin, Vincent ···························· 09.Wed.P3.49 Ashihara, Satoshi ····························· 08.Tue.B.4 Bock, Martin ···································· 10.Thu.C.5 Carell, Thomas ································ 10.Thu.D.4 Ashihara, Satoshi ······························· 11.Fri.A.5 INDEX Boge, Robert ··································· 09.Wed.C.7 Carey, Anne-Marie ··························· 08.Tue.C.5 Assion, Andreas ·························· 09.Wed.P3.52 Boivin, Maxime ································ 08.Tue.D.3 Carpeggiani, Poalo Antonio ··············· 08.Tue.A.5 Attias, André-Jean ······················· 08.Tue.P2.29 Bolognesi, Paola ··························· 09.Wed.P3.5 Cartella, Andrea ·························· 07.Mon.P1.48 Auger, Amelie ·································· 07.Mon.A.2 Bonca, Janez ······························ 07.Mon.P1.33 Cassette, Elsa ···································· 11.Fri.A.3 Avaldi, Lorenzo ····························· 09.Wed.P3.5 Bonn, Mischa ······························· 08.Tue.P2.21 Castiglioni, Luca ·························· 08.Tue.P2.40 Averitt, Richard D. ······················· 09.Wed.P3.43 Bonn, Mischa ·································· 09.Wed.B.4 Castro Neto, Antonio ························ 10.Thu.C.3 Ayuso, David ···································· 08.Tue.A.3 Borgschulte, Andreas ······················· 10.Thu.A.4 Cating, Emma ································· 09.Wed.E.5 Bache, Morten ····························· 08.Tue.P2.59 Borrego Varillas, Rocio ················· 08.Tue.P2.58 Cattoni, Andrea ···························· 08.Tue.P2.45 Bahrenburg, Julia ······················· 09.Wed.P3.20 Borrego Varillas, Rocio ················· 08.Tue.P2.60 Cavalleri, Andrea ····························· 07.Mon.D.1 Bakker, Huib ···································· 08.Tue.E.3 Borrego-Varillas, Rocio ················ 07.Mon.P1.11 Cavalleri, Andrea ····························· 07.Mon.D.4 Bakulin, Artem ································· 08.Tue.E.3 Bradler, Maximilian ····················· 07.Mon.P1.56 Cavalleri, Andrea ························· 07.Mon.P1.35 Bakulin, Artem ··································· 11.Fri.A.4 Bradler, Maximilian ·························· 08.Tue.D.4 Cavalleri, Andrea ························· 07.Mon.P1.47 Balciunas, Tadas ····························· 07.Mon.A.4 Brahlek, Matthew ···························· 09.Wed.B.7 Cavalleri, Andrea ························· 07.Mon.P1.48 Balciunas, Tadas ······························ 08.Tue.D.7 Brandt, Nathaniel C. ···················· 09.Wed.P3.43 Cavalleri, Andrea ·························· 08.Tue.P2.48 Balogh, Emeric ··························· 07.Mon.P1.60 Braun, Markus ···························· 09.Wed.P3.27 Caviezel, Andrin ······························ 07.Mon.D.5 Baltuska, Andrius ···························· 07.Mon.A.4 Bredenbeck, Jens ··························· 09.Wed.A.5 Caviezel, Andrin ······························ 07.Mon.D.6 Baltuska, Andrius ····························· 08.Tue.D.7 Bredenbeck, Jens ··························· 10.Thu.D.6 Caviglia, Andrea D. ·························· 07.Mon.D.4 Baltuska, Andrius ··························· 08.Tue.P2.3 Bree, Carsten ··································· 10.Thu.C.5 Cerullo, Giulio ····························· 07.Mon.P1.33 Baltuska, Andrius ··························· 08.Tue.P2.7 Breher, Frank ······························· 08.Tue.P2.28 Cerullo, Giulio ····························· 07.Mon.P1.36 Baltuska, Andrius ························· 08.Tue.P2.57 Bremer, Marshall T. ·························· 10.Thu.C.2 Cerullo, Giulio ····························· 07.Mon.P1.52 Baltuska, Andrius ···························· 09.Wed.C.6 Bressler, Christian ······················· 09.Wed.P3.57 Cerullo, Giulio ····························· 07.Mon.P1.55 Baltuška, Andrius ···························· 07.Mon.A.3 Brida, Daniele ····························· 07.Mon.P1.33 Cerullo, Giulio ·································· 08.Tue.C.5 Baltuška, Andrius ························· 08.Tue.P2.16 Brida, Daniele ····························· 07.Mon.P1.52 Cerullo, Giulio ································ 08.Tue.P2.7 Baltuška, Andrius ···························· 09.Wed.C.5 Brida, Daniele ······························ 08.Tue.P2.45 Cerullo, Giulio ······························ 08.Tue.P2.34 Banﬁ , Francesco ························· 07.Mon.P1.33 Brida, Daniele ································· 09.Wed.A.1 Cerullo, Giulio ······························ 08.Tue.P2.45 Banin, Uri ···································· 09.Wed.P3.28 Brida, Daniele ································· 09.Wed.B.1 Cerullo, Giulio ······························ 08.Tue.P2.58 Bao, Wenzhong ································ 10.Thu.C.3 Britz, Alexander ······························· 09.Wed.D.1 Cerullo, Giulio ································· 09.Wed.A.1 Baranov, Dmitry ··························· 08.Tue.P2.44 64 AUTHORS’ INDEX ▶

Cerullo, Giulio ····························· 09.Wed.P3.42 Cundiff, Steven T. ···························· 07.Mon.C.3 Durkin, Patrick ································ 10.Thu.D.6 Cerullo, Giulio ·································· 10.Thu.B.5 Cunha, Ana ·································· 08.Tue.P2.27 Durr, Hermann A. ························ 09.Wed.P3.44 Cha, Soonyoug ································ 09.Wed.B.7 Curmi, Paul M. ································· 08.Tue.C.4 Echternkamp, Katharina ··················· 08.Tue.B.4 Chabera, Pavel ································· 08.Tue.E.1 Dakovski, Georgi L. ························· 07.Mon.D.2 Echternkamp, Katharina ··················· 08.Tue.B.5 Chapman, Richard ······················ 07.Mon.P1.35 Dakovski, Georgi L. ························· 07.Mon.D.4 Egorova, Dassia ································· 11.Fri.A.4 Chapman, Richard ······················· 08.Tue.P2.48 Dal Conte, Stefano ······················ 07.Mon.P1.33 Eilanlou, A. Amani ························· 07.Mon.P1.6 Charalambidis, Dimitrios ·················· 08.Tue.A.5 Dal Conte, Stefano ······················ 07.Mon.P1.36 Eilanlou, A. Amani ························· 09.Wed.P3.4 Chen, Ching Hung ························ 08.Tue.P2.31 Dal Conte, Stefano ······················ 09.Wed.P3.42 Eilanlou, A. Amani ························· 09.Wed.P3.7 Chen, Deying ······························ 09.Wed.P3.10 Damascelli, Andrea ····················· 07.Mon.P1.33 Eliash, Tamar ······························· 08.Tue.P2.13 Chen, Hsueh-Ju ··························· 08.Tue.P2.31 Dantus, Marcos ··························· 07.Mon.P1.59 Ellis, Jennifer L. ·························· 07.Mon.P1.18 Chen, Jianhui ·································· 09.Wed.D.5 Dantus, Marcos ···························· 08.Tue.P2.23 Ellis, Jennifer L. ······························ 09.Wed.E.2 Chen, Ming-Chang ·························· 07.Mon.A.2 Dantus, Marcos ································ 10.Thu.C.2 Elsaesser, Thomas ·························· 07.Mon.A.3 Chen, Shaohao ································ 08.Tue.A.6 Dao, Lap V. ···································· 07.Mon.P1.4 Elsaesser, Thomas ·························· 07.Mon.E.2 Chen, Zhuoying ································ 08.Tue.E.3 Dao, Thang D. ····························· 07.Mon.P1.29 Elsaesser, Thomas ······················· 08.Tue.P2.46 Cheng, Cheng-Maw ····················· 08.Tue.P2.31 Dao, Thang D. ····························· 09.Wed.P3.29 Elsaesser, Thomas ··························· 10.Thu.A.4 Cheng, Ya ······································ 07.Mon.P1.2 Das, Susanta K. ······························· 10.Thu.C.5 Elsaesser, Thomas ··························· 10.Thu.C.5 Chergui, Majed ······························· 09.Wed.D.1 Davis, Jeffrey A. ······························· 08.Tue.C.4 Emaury, Florian ··························· 09.Wed.P3.59 Chevalier, Katharina ····················· 08.Tue.P2.28 Davis, Jeffrey A. ·························· 09.Wed.P3.46 Endo, Tomoyuki ······························ 08.Tue.P2.4 Chia, Shih-Hsuan ························ 07.Mon.P1.55 De Camillis, Simone ························· 08.Tue.A.3 Endo, Tomoyuki ······························ 08.Tue.P2.5 Chia, Shih-Hsuan ························ 09.Wed.P3.60 De Los Reyes, Glenda ······················ 08.Tue.B.6 Engels, Joachim W. ····················· 09.Wed.P3.27 Chiang, Cheng-Tien ···················· 07.Mon.P1.45 De Silvestri, Sandro ····················· 08.Tue.P2.58 Erattuphuza, Sonia ·························· 09.Wed.C.5 Chiang, Cheng-Tien ··························· 11.Fri.B.2 De Silvestri, Sandro ··························· 11.Fri.B.1 Erk, Benjamin ······························· 09.Wed.P3.3 Chiappe, Daniele ························· 09.Wed.P3.42 De Silvestri, Sandro ··························· 11.Fri.B.3 Ernstorfer, Ralph ····························· 07.Mon.D.7 Chiba, Yuhei ···································· 07.Mon.B.7 de Vivie-Riedle, Regina ··················· 07.Mon.B.4 Ernstorfer, Ralph ······························ 08.Tue.B.1 Chin, Alex ········································ 07.Mon.C.7 de Vivie-Riedle, Regina ··················· 09.Wed.D.4 Ernstorfer, Ralph ························· 09.Wed.P3.53 Chin, Alex ··········································· 11.Fri.A.4 de Vivie-Riedle, Regina ··················· 10.Thu.D.3 Essig, Martin ··································· 10.Thu.D.6 Chipperﬁ eld, Luke ··························· 07.Mon.A.4 Decleva, Piero ·································· 08.Tue.A.3 Facciala, Davide ································· 11.Fri.B.1 Cho, Byungmoon ························· 08.Tue.P2.44 Dekorsy, Thomas ························ 07.Mon.P1.41 Faccialà, Davide ································· 11.Fri.B.3 Cho, Hana ······································· 09.Wed.D.2 Della Valle, Giuseppe ···················· 08.Tue.P2.45 Faccio, Daniele ···························· 08.Tue.P2.57 Cho, Hana ······································· 09.Wed.D.3 Demircan, Ayhan ······························ 10.Thu.C.5 Fallahi, Arya ································ 09.Wed.P3.37 Choi, Hyunyong ··························· 07.Mon.P1.30 Demsar, Jure ·································· 07.Mon.D.5 Fan, Guangyu ·································· 07.Mon.A.4 Choi, Hyunyong ······························· 09.Wed.B.7 Demsar, Jure ······························ 07.Mon.P1.41 Fan, Guangyu ··································· 08.Tue.D.7 Chollet, Matthieu ····························· 07.Mon.D.1 Deng, Yunpei ······························· 09.Wed.P3.53 Fan, Kebin ··································· 09.Wed.P3.43 Chollet, Matthieu ····························· 07.Mon.D.6 Derlet, Peter ································ 09.Wed.P3.35 Fan, Tingting ······························· 07.Mon.P1.54 Chollet, Matthieu ····························· 09.Wed.E.1 Devetta, Michele ································ 11.Fri.B.1 Fanciulli, Marco ·························· 09.Wed.P3.42 Chou, Fang-Cheng ······················· 08.Tue.P2.31 Devetta, Michele ································ 11.Fri.B.3 Fang, Shaobo ······························ 07.Mon.P1.55 INDEX Christesen, Joseph ························· 09.Wed.E.5 Dewa, Takehisa ································ 08.Tue.C.6 Fang, Shaobo ······························ 09.Wed.P3.37 Chu, Wei ······································· 07.Mon.P1.2 Dhesi, Sarnjeet S. ··························· 07.Mon.D.4 Fang, Shaobo ······························ 09.Wed.P3.60 Chu, Wei-Chun ································· 08.Tue.A.2 Diebold, Andreas ························· 09.Wed.P3.59 Farinello, Paolo ··························· 07.Mon.P1.55 Chuang, Yi-De ································· 07.Mon.D.4 Diesing, Detlef ···························· 09.Wed.P3.47 Farinello, Paolo ································ 10.Thu.B.5 Cinquanta, Eugenio ····················· 09.Wed.P3.42 Differt, Dominik ··························· 09.Wed.P3.47 Faust, Adam ································ 09.Wed.P3.28 Cirelli, Claudio ······························ 08.Tue.P2.10 Diller, Rolf ···································· 08.Tue.P2.28 Fechner, Michael ····························· 07.Mon.D.1 Cirelli, Claudio ································· 09.Wed.C.7 Ding, Chengyuan ························ 07.Mon.P1.18 Fedulova, Elena ································ 10.Thu.C.6 Cirmi, Giovanni ··························· 07.Mon.P1.55 Ding, Chengyuan ························ 07.Mon.P1.54 Fei, Zhe ············································ 10.Thu.C.3 Cirmi, Giovanni ··························· 09.Wed.P3.37 Ding, Chengyuan ···························· 09.Wed.E.2 Feifel, Raimund ····························· 09.Wed.P3.3 Cirmi, Giovanni ··························· 09.Wed.P3.60 Dinh, Khuong B. ···························· 07.Mon.P1.4 Fejer, Martin M. ···························· 08.Tue.P2.56 Clark, Jenny ···································· 07.Mon.C.7 Doblhoff-Dier, Katharina ·················· 09.Wed.C.5 Feldmann, Jochen ······················ 09.Wed.P3.33 Clark, Jesse N. ································ 09.Wed.E.1 Dollar, Franklin ································ 07.Mon.A.2 Feng, Chengyong ····························· 08.Tue.A.2 Cocke, C. Lew ···································· 11.Fri.B.4 Dollar, Franklin ································ 09.Wed.E.2 Feng, Xinliang ································· 09.Wed.B.4 Cocker, Tyler ···································· 08.Tue.B.6 Dombi, Péter ···································· 10.Thu.C.6 Fennel, Franziska ···························· 07.Mon.B.6 Cogdell, Richard ·························· 07.Mon.P1.12 Dominguez, Pablo Nahuel ··········· 09.Wed.P3.11 Fennel, Thomas ···························· 09.Wed.P3.2 Cogdell, Richard ······························· 08.Tue.C.3 Dong, Shuo ································· 09.Wed.P3.15 Fennel, Thomas ·························· 09.Wed.P3.39 Cogdell, Richard ······························· 08.Tue.C.5 Dong, Zhiwei ······························· 09.Wed.P3.10 Ferrante, Carino ································· 11.Fri.A.6 Cogdell, Richard ·························· 09.Wed.P3.11 Dorfman, Konstantin E. ··················· 09.Wed.A.2 Ferrer, Andres ································· 07.Mon.D.5 Cohen, Oren ····································· 10.Thu.B.1 Dorfman, Konstantin E. ··················· 09.Wed.D.6 Ferrer, Andres ································· 07.Mon.D.6 Cordones-Hahn, Amy ······················ 09.Wed.D.3 Dorfman, Konstantin E. ··············· 09.Wed.P3.22 Ferrini, Gabriele ·························· 07.Mon.P1.33 Corkum, Paul B. ······························ 09.Wed.C.6 Dornes, Christian ···························· 07.Mon.D.5 Feulner, Peter ··································· 10.Thu.B.2 Corthey, Gaston ··························· 08.Tue.P2.35 Dornes, Christian ···························· 07.Mon.D.6 Fidder, Henk ······································· 11.Fri.A.1 Costard, Rene ································· 07.Mon.E.2 Doumy, Gilles ·································· 09.Wed.D.1 Fiechter, Sebastian ··························· 10.Thu.B.3 Costard, Rene ···································· 11.Fri.A.1 Dube, Henry ···································· 09.Wed.D.4 Field, Ryan L. ······························· 08.Tue.P2.22 Courtney, Trevor L. ······················· 08.Tue.P2.44 Dubrouil, Antoine ····························· 08.Tue.A.2 Field, Ryan L. ······························· 08.Tue.P2.37 Courtney, Trevor L. ·························· 09.Wed.A.3 Dudovich, Nirit ··································· 11.Fri.B.1 Fingerhut, Benjamin ························ 09.Wed.D.6 Cregut, Olivier ····························· 09.Wed.P3.57 Dudovich, Nirit ··································· 11.Fri.B.3 Fischer, Jonathan ···························· 09.Wed.B.1 Crozatier, Vincent ························ 09.Wed.P3.52 Dudovich, Nirit ··································· 11.Fri.B.5 Fleischer, Avner ······························· 10.Thu.B.1 Cundiff, Steven T. ···························· 07.Mon.C.1 Dukovic, Gordana ························ 07.Mon.P1.18 Fleming, Graham R. ························· 08.Tue.C.2 65 ▶ AUTHORS’ INDEX

Fleming, Graham R. ····················· 08.Tue.P2.24 Gascon, Jorge ······························ 08.Tue.P2.21 Guo, Lanjun ·································· 09.Wed.P3.1 Fleming, Graham R. ···················· 09.Wed.P3.24 Gatti, Fabien ································ 08.Tue.P2.20 Gupta, Manisha ································ 08.Tue.B.6 Flytzanis, Christos ························ 08.Tue.P2.46 Gawelda, Wojciech ······················· 08.Tue.P2.37 Gusev, Vitalyi ······························· 07.Mon.P1.41 Foerst, Michael ······························· 07.Mon.D.1 Gawelda, Wojciech ·························· 09.Wed.D.1 Haacke, Stefan ··························· 09.Wed.P3.12 Fogler, Michael ································ 10.Thu.C.3 Gawelda, Wojciech ·························· 09.Wed.D.7 Haacke, Stefan ··························· 09.Wed.P3.26 Fonin, Mikhail ····························· 07.Mon.P1.41 Gdor, Itay ········································ 07.Mon.C.6 Haacke, Stefan ··························· 09.Wed.P3.57 Fons, Paul ···································· 08.Tue.P2.43 Gdor, Itay ····································· 08.Tue.P2.13 Hada, Masaki ······························· 08.Tue.P2.35 Fons, Paul ··································· 09.Wed.P3.34 Gdor, Itay ···································· 09.Wed.P3.28 Hada, Masaki ······························ 09.Wed.P3.38 Foord, Mark E. ································ 09.Wed.E.2 Gedik, Nuh ······································· 10.Thu.A.2 Haessler, Stefan ······························ 07.Mon.A.4 Forbes, Andrew ···························· 08.Tue.P2.60 Geiseler, Henning ···························· 09.Wed.C.4 Haessler, Stefan ······························· 08.Tue.D.7 Forget, Nicolas ···························· 09.Wed.P3.58 Gelinas, Simon ································ 07.Mon.C.7 Haglund Jr, Richard F. ······················ 10.Thu.A.5 Först, Michael ································· 07.Mon.D.4 Gelinas, Simon ································· 08.Tue.E.3 Hall, Christopher R. ····················· 09.Wed.P3.46 Först, Michael ····························· 07.Mon.P1.48 Gelzinis, Andrius ······························ 08.Tue.C.1 Hamada, Norio ····························· 08.Tue.P2.12 Foucar, Lutz ·································· 09.Wed.P3.3 George, Antoine ······························ 07.Mon.D.1 Hamada, Yuki ··································· 10.Thu.A.1 Fourcade-Dutin, Coralie ··················· 08.Tue.D.7 Gerl, Michael ··································· 10.Thu.B.2 Hannaford, Peter ··························· 07.Mon.P1.4 Fourmeaux, Sylvain ····················· 09.Wed.P3.49 Gessner, Oliver ···························· 09.Wed.P3.14 Hara, Toru ··································· 07.Mon.P1.50 Fox, Zachary W. ······························· 09.Wed.A.3 Ghosh, Hirendra ·························· 07.Mon.P1.31 Harabuchi, Yu ······························ 07.Mon.P1.17 Frano, Alex ······································ 07.Mon.D.1 Giannetti, Claudio ························ 07.Mon.P1.33 Harabuchi, Yu ······························· 08.Tue.P2.14 Frassetto, Fabio ······························· 08.Tue.A.2 Gierz, Isabella ····························· 07.Mon.P1.35 Harder, Ross ··································· 09.Wed.E.1 Frassetto, Fabio ······························· 08.Tue.A.3 Gierz, Isabella ····························· 07.Mon.P1.47 Harlang, Tobias ································ 08.Tue.E.1 Frédéric, Gerome ····························· 08.Tue.D.7 Gierz, Isabella ······························ 08.Tue.P2.48 Harris, Charles ···························· 07.Mon.P1.22 Freeman, Mark ································ 08.Tue.B.6 Giguére, Mathieu ···························· 07.Mon.B.2 Hase, Muneaki ····························· 08.Tue.P2.43 Friedriszik, Frank ························ 07.Mon.P1.14 Gindensperger, Etienne ··············· 09.Wed.P3.12 Hase, Muneaki ···························· 09.Wed.P3.34 Friend, Richard ······························· 07.Mon.C.7 Glans, Per-Anders ······················· 09.Wed.P3.14 Hasegawa, Hirokazu ··················· 07.Mon.P1.15 Friend, Richard ································ 08.Tue.E.3 Gliserin, Alexander ·························· 09.Wed.C.1 Hasegawa, Hirokazu ···················· 08.Tue.P2.19 Fritz, David ····································· 09.Wed.E.1 Gliserin, Alexander ······················ 09.Wed.P3.45 Hasegawa, Hirokazu ··················· 09.Wed.P3.17 Fuji, Takao ·································· 07.Mon.P1.43 Glownia, James ······························ 07.Mon.D.1 Hashimoto, Hideki ······················· 07.Mon.P1.12 Fuji, Takao ······································· 08.Tue.D.1 Glownia, James ······························ 07.Mon.D.6 Hashimoto, Hideki ···························· 08.Tue.C.7 Fuji, Takao ··································· 08.Tue.P2.50 Godt, Adelheid ···························· 09.Wed.P3.47 Hashimoto, Hideki ······················· 09.Wed.P3.25 Fujii, Naoki ·································· 07.Mon.P1.13 Golde, Daniel ··································· 10.Thu.A.3 Hata, Daiki ······································ 09.Wed.B.6 Fujii, Ritsuko ······························· 07.Mon.P1.12 Goldﬂ a, Michael ······························· 10.Thu.C.3 Hatsui, Takaki ································· 09.Wed.D.5 Fujimoto, Koukichi ·························· 09.Wed.B.6 Golez, Denis ································ 07.Mon.P1.33 Hatsui, Takaki ······························· 09.Wed.P3.3 Fujimura, Yuichi ·························· 07.Mon.P1.25 Golling, Matthias ························· 09.Wed.P3.59 Hauri, Christoph P. ··························· 09.Wed.B.2 Fujisawa, Tomotsumi ··················· 08.Tue.P2.26 González, Leticia ····························· 10.Thu.D.1 Hauri, Christoph P. ······················· 09.Wed.P3.35 Fujita, Hiroyuki ································· 10.Thu.A.1 Goto, Kazuki ································ 09.Wed.P3.41 Hauser, Andreas ······························ 09.Wed.E.6 Fujiwara, Takehisa ······················ 07.Mon.P1.17 Gotoh, Hideki ······························ 09.Wed.P3.55 Hayashi, Shingo ·························· 07.Mon.P1.44 Fujiwara, Takehisa ······················· 08.Tue.P2.14 Goulielmakis, Eleftherios ·················· 10.Thu.B.4 Hayashi, Shingo ·························· 09.Wed.P3.38 Fukahori, Shinichi ························· 07.Mon.P1.8 Govorov, Alexander O. ················· 09.Wed.P3.33 Hayashita, Hironori ······················ 07.Mon.P1.46

INDEX Fukumoto, Keiki ······························ 09.Wed.E.3 Grabielle, Stéphanie ···················· 09.Wed.P3.58 Hayashita, Hironori ························ 09.Wed.P3.3 Fukuzawa, Hironobu ··················· 07.Mon.P1.46 Gräfe, Stefanie ································ 09.Wed.C.5 Hayashita, Hironori ························ 09.Wed.P3.5 Fukuzawa, Hironobu ······················· 09.Wed.D.5 Graupner, Franziska ···················· 09.Wed.P3.27 Hayes, Stuart ······························· 08.Tue.P2.35 Fukuzawa, Hironobu ····················· 09.Wed.P3.3 Gray, Alexander X. ······················· 09.Wed.P3.44 He, Chuan ··································· 07.Mon.P1.41 Fukuzawa, Hironobu ····················· 09.Wed.P3.5 Gray, David ······································ 08.Tue.A.5 He, Feng ······································ 08.Tue.P2.17 Fuller, Franklin D. ····························· 08.Tue.C.1 Grazianetti, Carlo ························ 09.Wed.P3.42 He, Ping ······································ 09.Wed.P3.10 Fülöp, József A. ······························· 09.Wed.B.3 Greenwood, Jason ··························· 08.Tue.A.3 Healion, Daniel ···························· 09.Wed.P3.22 Furukawa, Yusuke ························· 07.Mon.P1.6 Greif, Michael ······························ 08.Tue.P2.40 Hebeisen, Christoph ························ 07.Mon.B.2 Furukawa, Yusuke ························· 09.Wed.P3.4 Greve, Christian ································· 11.Fri.A.1 Hebling, János ································ 09.Wed.B.3 Furukawa, Yusuke ························· 09.Wed.P3.7 Grilj, Jakob ···································· 08.Tue.P2.6 Heesemann, Ingo ························ 09.Wed.P3.47 Fushitani, Mizuho ·························· 07.Mon.P1.5 Grilj, Jakob ································· 09.Wed.P3.44 Hefner, Timo ································ 08.Tue.P2.34 Fushitani, Mizuho ··························· 08.Tue.P2.4 Gross, Petra ····································· 10.Thu.B.5 Hegmann, Frank A. ··························· 08.Tue.B.6 Fushitani, Mizuho ··························· 08.Tue.P2.5 Grossmann, Martin ····················· 07.Mon.P1.41 Heinz, Tony F. ··································· 08.Tue.E.2 Fushitani, Mizuho ························ 09.Wed.P3.23 Grozema, Ferdinand ····················· 08.Tue.P2.21 Heinzmann, Ulrich ···························· 10.Thu.B.3 Fusi, Stefania ······························ 09.Wed.P3.12 Gruebel, Sebastian ·························· 07.Mon.D.5 Heisler, Ismael A. ····························· 07.Mon.E.2 Gaarde, Mette B. ······························ 08.Tue.A.6 Grumstrup, Erik ······························· 09.Wed.E.5 Helbing, Jan ································ 07.Mon.P1.52 Gabriel, Michelle ····························· 09.Wed.E.5 Grünewald, Christian ··················· 09.Wed.P3.27 Hemmer, Michael ···························· 09.Wed.C.3 Gaffney, Jim A. ································ 09.Wed.E.2 Grunwald, Rüdiger ··························· 10.Thu.C.5 Hengsberger, Matthias ················· 08.Tue.P2.40 Gallardo Gonzalez, Isabel ············· 08.Tue.P2.60 Grupp, Alexander ····························· 10.Thu.A.5 Henry, Sarah ···································· 08.Tue.C.5 Gallmann, Lukas ······························ 08.Tue.A.6 Grychtol, Patrick ······························ 10.Thu.B.1 Hensen, Matthias ························ 09.Wed.P3.47 Gallmann, Lukas ·························· 08.Tue.P2.40 Gueye, Moussa ··························· 09.Wed.P3.12 Hensen, Matthias ····························· 10.Thu.B.3 Gallmann, Lukas ·························· 08.Tue.P2.56 Guggenmos, Alexander ···················· 10.Thu.B.4 Herink, Georg ··································· 08.Tue.B.4 Galloway, Benjamin ························· 07.Mon.A.2 Gühr, Markus ································· 08.Tue.P2.6 Herink, Georg ··································· 08.Tue.B.5 Gao, Meng ······································ 09.Wed.D.7 Gühr, Markus ······························ 09.Wed.P3.44 Hernandez-Garcia, Carlos ··············· 07.Mon.A.2 Gao, Meng ·································· 09.Wed.P3.36 Gulde, Max ······································ 08.Tue.B.5 Herrmann, Jens ······························· 08.Tue.A.6 Gardiner, Alastair ························· 09.Wed.P3.11 Guo, Hairun ·································· 08.Tue.P2.59 Hertel, Tobias ······························· 08.Tue.P2.34 Garg, Manish ··································· 10.Thu.B.4 Guo, Jinghua ······························ 09.Wed.P3.14 Herz, Julia ········································ 08.Tue.E.6 66 AUTHORS’ INDEX ▶

Hettich, Mike ······························ 07.Mon.P1.41 Ikeda, Naoshi ······························· 08.Tue.P2.41 Iwasaki, Atsushi ····························· 08.Tue.P2.3 Heuser, Sebastian ··························· 09.Wed.C.7 Ikeda, Yuki ·································· 09.Wed.P3.17 Iwasaki, Atsushi ··························· 08.Tue.P2.19 Heyer, Elodie ······························· 09.Wed.P3.26 Imanbaew, Dimitri ························ 08.Tue.P2.28 Iwasaki, Atsushi ·························· 09.Wed.P3.17 Hickstein, Daniel ························· 07.Mon.P1.18 Imura, Kohei ··································· 09.Wed.E.4 Iwaszczuk, Krzysztof ···················· 08.Tue.P2.42 Hickstein, Daniel ························· 07.Mon.P1.54 In, Chihun ··································· 07.Mon.P1.30 Iwata, Jun-Ichi ································ 07.Mon.C.5 Hickstein, Daniel ····························· 09.Wed.E.2 Inagaki, Akiko ···································· 11.Fri.A.7 Iyer, E Siva Subramaniam ············ 08.Tue.P2.13 Higginbotham, Andrew ···················· 09.Wed.E.1 Ingold, Gerhard ······························· 07.Mon.D.5 Jain, Arohi ········································ 10.Thu.B.4 Higuchi, Takuya ································ 10.Thu.B.7 Ingold, Gerhard ······························· 07.Mon.D.6 Jakubeit, Clemens ··························· 10.Thu.C.6 Higuchi, Takyua ··························· 09.Wed.P3.30 Inoue, Ken-ichi ···························· 07.Mon.P1.27 Jansen, Thomas ··························· 08.Tue.P2.27 Hikosaka, Yasumasa ······················ 08.Tue.P2.4 Inubushi, Yuichi ······························· 07.Mon.B.7 Jarillo-Herrero, Pablo ······················· 10.Thu.A.2 Hikosaka, Yasumasa ······················ 08.Tue.P2.5 Inubushi, Yuichi ··························· 07.Mon.P1.51 Jaron-Becker, Agnieszka ················· 07.Mon.A.2 Himmelstoss, Matthias ················ 09.Wed.P3.11 Inubushi, Yuichi ······························· 09.Wed.D.5 Javier Castro Pelaez, Pedro ·········· 08.Tue.P2.20 Hiraoka, Sho ······························· 07.Mon.P1.23 Inubushi, Yuichi ····························· 09.Wed.P3.3 Jelic, Vedran ···································· 08.Tue.B.6 Hirori, Hideki ··································· 09.Wed.B.5 Ishida, Kakuta ································ 08.Tue.P2.2 Jensen, Søren A. ····························· 09.Wed.B.4 Hirosawa, Kenichi ···························· 08.Tue.B.2 Ishida, Yukiaki ····························· 07.Mon.P1.34 Jeong, Jaewoo ··························· 09.Wed.P3.44 Hirosawa, Kenichi ························ 08.Tue.P2.55 Ishihara, Hajime ··························· 08.Tue.P2.47 Jepsen, Peter Uhd ························ 08.Tue.P2.42 Hirosawa, Kenichi ···························· 10.Thu.C.4 Ishihara, Sumio ··························· 07.Mon.P1.40 Jia, Quanxi ······································ 07.Mon.D.3 Hishikawa, Akiyoshi ······················ 07.Mon.P1.5 Ishihara, Sumio ···························· 08.Tue.P2.41 Jiang, Yifeng ································ 08.Tue.P2.37 Hishikawa, Akiyoshi ······················· 08.Tue.P2.4 Ishihara, Sumio ··························· 09.Wed.P3.40 Jiang, Yifeng ··································· 09.Wed.D.7 Hishikawa, Akiyoshi ······················· 08.Tue.P2.5 Ishii, Nobuhisa ···························· 07.Mon.P1.53 Jiang, Yifeng ······························· 09.Wed.P3.36 Hishikawa, Akiyoshi ····················· 08.Tue.P2.18 Ishii, Nobuhisa ····························· 08.Tue.P2.51 Jiang, Yuhai ···································· 09.Wed.D.5 Hishikawa, Akiyoshi ···················· 09.Wed.P3.23 Ishii, Nobuhisa ································ 09.Wed.C.4 Jimenez, Jose L. ························· 07.Mon.P1.18 Hobbs, Richard ································ 08.Tue.B.3 Ishikawa, Haruto ························· 07.Mon.P1.13 Jimenez, Jose L. ····························· 09.Wed.E.2 Höfer, Ulrich ···································· 07.Mon.C.2 Ishikawa, Kenichi L. ······················ 07.Mon.P1.3 Jin, Cheng ······································ 07.Mon.A.5 Hoffman, James ······························ 08.Tue.B.6 Ishikawa, Kenichi L. ······················· 08.Tue.P2.1 Jing, Chengrui ······························ 07.Mon.P1.2 Hoffmann, Matthias C. ···················· 07.Mon.D.2 Ishikawa, Kenichi L. ······················ 09.Wed.P3.5 Johnson, Jeremy A. ························· 07.Mon.D.5 Hoffmann, Matthias C. ····················· 10.Thu.C.5 Ishikawa, Manabu ······················· 09.Wed.P3.36 Johnson, Jeremy A. ························· 07.Mon.D.6 Hofman, Michael ······························ 10.Thu.C.5 Ishikawa, Tadahiko ······················· 08.Tue.P2.35 Johnson, Steven L. ·························· 07.Mon.D.5 Hofmann, Cornelia ······················· 08.Tue.P2.10 Ishikawa, Takahiro ······················ 07.Mon.P1.40 Johnson, Steven L. ·························· 07.Mon.D.6 Hohenleutner, Matthias ···················· 10.Thu.A.3 Ishikawa, Takahiro ······················· 08.Tue.P2.41 Johnsson, Per ······························· 09.Wed.P3.3 Holtz, Marcel ··································· 07.Mon.A.3 Ishikawa, Takahiro ······················ 09.Wed.P3.40 Jonas, David ································ 08.Tue.P2.44 Holtz, Marcel ···································· 10.Thu.A.4 Ishikawa, Tetsuya ······················· 07.Mon.P1.50 Joo, Taiha ··································· 09.Wed.P3.18 Hommelhoff, Peter ······················ 09.Wed.P3.30 Ishikawa, Tetsuya ·························· 08.Tue.P2.4 Juang, Jenh-Yih ··························· 08.Tue.P2.31 Honda, Asami ··································· 08.Tue.D.5 Ishikawa, Tetsuya ·························· 08.Tue.P2.5 Jun, Seong Chan ························· 07.Mon.P1.30 Hong, Kiryong ································· 09.Wed.D.2 Ishioka, Kunie ································· 07.Mon.C.2 Jurek, Zoltan ································· 09.Wed.P3.3 Horiuchi, Sachio ······························ 09.Wed.B.6 Ishioka, Kunie ····························· 09.Wed.P3.31 Juvé, Vincent ·································· 07.Mon.A.3 INDEX Horvath, Zoltan L. ························ 07.Mon.P1.37 Ishizaki, Akihito ···························· 08.Tue.P2.24 Juvé, Vincent ··································· 10.Thu.A.4 Hosaka, Aruto ······························ 08.Tue.P2.55 Ishizaki, Akihito ··························· 09.Wed.P3.24 Kabachnik, Nikolay ······················· 09.Wed.P3.5 Houtepen, Arjan ··························· 08.Tue.P2.21 Isokawa, Yusuke ····························· 07.Mon.B.7 Kaertner, Franz ································· 08.Tue.B.3 Hu, Wanzheng ····························· 07.Mon.P1.47 Itakura, Ryuji ································· 07.Mon.P1.8 Kageyama, Hiroshi ·························· 09.Wed.B.5 Hua, Weijie ·································· 09.Wed.P3.22 Itakura, Ryuji ································· 09.Wed.P3.9 Kaiser, Stefan ······························ 07.Mon.P1.35 Huang, Cheng ······························· 07.Mon.P1.7 Itatani, Jiro ································· 07.Mon.P1.53 Kaiser, Stefan ······························ 07.Mon.P1.47 Huang, Pei-Chi ································ 07.Mon.A.2 Itatani, Jiro ·································· 08.Tue.P2.51 Kajikawa, Jumpei ························· 09.Wed.P3.3 Huang, Shi-Wen ······························ 07.Mon.D.6 Itatani, Jiro ····································· 09.Wed.C.4 Kajikawa, Takayuki ····················· 09.Wed.P3.25 Huber, Lucas ··································· 07.Mon.D.5 Ito, Syoji ······································ 09.Wed.P3.19 Kambe, Takashi ··························· 08.Tue.P2.41 Huber, Rupert ··································· 10.Thu.A.3 Ito, Yuta ······································· 07.Mon.P1.25 Kamikubo, Hironari ························· 10.Thu.D.5 Huber, Tim ······································ 07.Mon.D.5 Ito, Yuta ·········································· 08.Tue.P2.9 Kanai, Teruto ······························· 07.Mon.P1.53 Huber, Tim ······································ 07.Mon.D.6 Ito, Yuta ··········································· 09.Wed.D.5 Kanai, Teruto ································ 08.Tue.P2.51 Hummert, Johan ······························ 08.Tue.A.2 Ito, Yuta ········································· 09.Wed.P3.3 Kanai, Teruto ··································· 09.Wed.C.4 Hunger, Johannes ························ 08.Tue.P2.21 Itoh, Hirotake ······························ 07.Mon.P1.40 Kandada, Ajay R. ························· 09.Wed.P3.33 Hunt, Cassandra R. ····················· 07.Mon.P1.47 Itoh, Hirotake ······························· 08.Tue.P2.41 Kaneshima, Keisuke ···················· 07.Mon.P1.53 Hurkmans, Martijn ······················· 08.Tue.P2.21 Itoh, Hirotake ······························ 09.Wed.P3.40 Kaneshima, Keisuke ························ 09.Wed.C.4 Huse, Nils ······································· 09.Wed.D.2 Itoh, Hirotake ······························ 09.Wed.P3.41 Kannari, Fumihiko ···························· 08.Tue.B.2 Huth, Michael ····························· 07.Mon.P1.45 Itoh, Keisuke ································ 08.Tue.P2.41 Kannari, Fumihiko ························ 08.Tue.P2.55 Huth, Michael ···································· 11.Fri.B.2 Itoh, Keisuke ······························· 09.Wed.P3.41 Kannari, Fumihiko ······················· 09.Wed.P3.54 Huttner, Ulrich ·································· 10.Thu.A.3 Itoh, Yuta ······································· 07.Mon.P1.9 Kannari, Fumihiko ···························· 10.Thu.C.4 Hwang, Harold Y. ························· 09.Wed.P3.43 Ivanov, Igor ····································· 09.Wed.C.6 Kanno, Manabu ··························· 07.Mon.P1.21 Hyyti, Janne ····································· 10.Thu.C.5 Ivanov, Ivan ····································· 09.Wed.B.4 Kanno, Manabu ··························· 07.Mon.P1.25 Ibrahim, Heide ································ 07.Mon.B.2 Iwai, Shinichiro ··························· 07.Mon.P1.40 Kano, Jun ···································· 08.Tue.P2.41 Ichimiya, Masayoshi ····················· 08.Tue.P2.47 Iwai, Shinichiro ···························· 08.Tue.P2.41 Kanya, Reika ·································· 08.Tue.P2.2 Ichimura, Junichi ························ 09.Wed.P3.40 Iwai, Shinichiro ··························· 09.Wed.P3.40 Kanya, Reika ··································· 09.Wed.C.2 Ichimura, Junichi ························ 09.Wed.P3.41 Iwai, Shinichiro ··························· 09.Wed.P3.41 Kanya, Reika ······························· 09.Wed.P3.21 Ide, Yoshihiro ······························ 07.Mon.P1.16 Iwamura, Munetaka ····················· 08.Tue.P2.15 Kao, Chih-Hsien ······························· 08.Tue.D.2 Igarashi, Kyushiro ······················· 07.Mon.P1.44 Iwasaki, Atsushi ·························· 07.Mon.P1.10 Kapteijn, Freek ····························· 08.Tue.P2.21 Iikubo, Ryo ·································· 07.Mon.P1.17 Iwasaki, Atsushi ·························· 07.Mon.P1.50 Kapteyn, Henry ······························· 07.Mon.A.2 67 ▶ AUTHORS’ INDEX

Kapteyn, Henry ··························· 07.Mon.P1.18 Kheifets, Anatoli ······························ 09.Wed.C.6 Koshihara, Shin-ya ······················· 08.Tue.P2.35 Kapteyn, Henry ··························· 07.Mon.P1.54 Kida, Noriaki ··································· 09.Wed.B.6 Koshihara, Shin-ya ·························· 09.Wed.E.3 Kapteyn, Henry ······························· 09.Wed.E.2 Kiefer, Laura ······························· 07.Mon.P1.28 Kosumi, Daisuke ························· 07.Mon.P1.12 Kapteyn, Henry ································ 10.Thu.B.1 Kiefer, Laura ······································ 11.Fri.A.2 Kosumi, Daisuke ························· 09.Wed.P3.25 Karashima, Shutaro ························ 07.Mon.B.7 Kieffer, Jean-Claude ························ 07.Mon.B.2 Kovacs, Attila P. ··························· 07.Mon.P1.37 Karpowicz, Nicholas ························· 10.Thu.B.6 Kieffer, Jean-Claude ···················· 09.Wed.P3.49 Kozlov, Oleg V. ·································· 08.Tue.E.7 Karpowicz, Nicholas ························· 10.Thu.C.6 Kielpinski, Dave ··························· 08.Tue.P2.17 Krausz, Ferenc ································ 09.Wed.B.3 Karsch, Stefan ································ 09.Wed.B.3 Kienberger, Reinhard ························ 10.Thu.B.2 Krausz, Ferenc ································ 09.Wed.C.1 Kartashov, Daniil ···························· 08.Tue.P2.3 Kienitz, Jens M. ·························· 09.Wed.P3.37 Krausz, Ferenc ···························· 09.Wed.P3.45 Kartashov, Daniil ···························· 08.Tue.P2.7 Kim, Dong Eon ································ 09.Wed.D.5 Krausz, Ferenc ································· 10.Thu.B.2 Kartashov, Daniil ·························· 08.Tue.P2.16 Kim, Eun Sun ······························· 08.Tue.P2.29 Krausz, Ferenc ································· 10.Thu.B.4 Kartashov, Daniil ·························· 08.Tue.P2.57 Kim, Jaeseok ······························ 07.Mon.P1.30 Krausz, Ferenc ································· 10.Thu.B.6 Kartashov, Daniil ····························· 09.Wed.C.5 Kim, Sangkyu ····························· 09.Wed.P3.18 Krausz, Ferenc ································· 10.Thu.C.6 Kartashov, Daniil ····························· 09.Wed.C.6 Kim, So Young ····························· 09.Wed.P3.18 Kriegel, Ilka ································· 09.Wed.P3.33 Kärtner, Franz X. ·························· 07.Mon.P1.55 Kim, Tae Kyu ··································· 09.Wed.D.2 Krogen, Peter R. ······························· 08.Tue.D.6 Kärtner, Franz X. ·························· 07.Mon.P1.58 Kim, Tae Kyu ··································· 09.Wed.D.3 Kruchinin, Stanislav ························· 10.Thu.B.6 Kärtner, Franz X. ······························· 08.Tue.D.6 Kiman, Kana ···································· 10.Thu.C.1 Ku, Shi-an ······································· 07.Mon.A.3 Kärtner, Franz X. ······························ 09.Wed.A.6 Kimel, Alexey ······························ 07.Mon.P1.48 Ku, Shin-An ·································· 08.Tue.P2.31 Kärtner, Franz X. ·························· 09.Wed.P3.37 Kimura, Miku ································ 09.Wed.P3.3 Kubacka, Teresa ······························ 07.Mon.D.5 Kärtner, Franz X. ·························· 09.Wed.P3.60 King, John T. ··································· 07.Mon.E.3 Kubacka, Teresa ······························ 07.Mon.D.6 Kasmi, Lamia ··································· 08.Tue.A.6 King, John T. ······························· 07.Mon.P1.28 Kubarych, Kevin J. ·························· 07.Mon.E.3 Kasmi, Lamia ··································· 08.Tue.D.4 King, John T. ······································ 11.Fri.A.2 Kubarych, Kevin J. ······················ 07.Mon.P1.28 Kataoka, Mikio ································ 10.Thu.D.5 Kinoshita, Takashi ························ 08.Tue.P2.47 Kubarych, Kevin J. ····························· 11.Fri.A.2 Katayama, Ikufumi ······················ 07.Mon.P1.29 Kira, Mackillo ·································· 07.Mon.C.1 Kübel, Matthias ······························· 07.Mon.B.4 Katayama, Ikufumi ······················ 07.Mon.P1.42 Kira, Mackillo ··································· 10.Thu.A.3 Kuhlman, Thomas S. ······················· 07.Mon.B.5 Katayama, Ikufumi ······················· 08.Tue.P2.38 Kirchner, Friedrich O. ··················· 09.Wed.P3.45 Kühn, Oliver ···································· 07.Mon.B.6 Katayama, Ikufumi ······················ 09.Wed.P3.29 Kirschbrown, Justin ························ 09.Wed.E.5 Kukk, Edwin ···································· 09.Wed.D.5 Katayama, Tetsuo ··························· 07.Mon.B.7 Kirschner, Jürgen ························ 07.Mon.P1.45 Kukk, Edwin ·································· 09.Wed.P3.3 Katayama, Tetsuo ······················· 07.Mon.P1.51 Kirschner, Jürgen ······························· 11.Fri.B.2 Kukura, Philipp ···························· 09.Wed.P3.56 Katayama, Tetsuro ··························· 08.Tue.C.6 Kishida, Hideo ····························· 09.Wed.P3.40 Kumada, Takayuki ························· 09.Wed.P3.9 Katayama, Tetsuro ······················ 09.Wed.P3.19 Kishida, Hideo ····························· 09.Wed.P3.41 Kumar, Abhishek ····························· 07.Mon.C.7 Kato, Keigo ································· 09.Wed.P3.38 Kitajima, Masahiro ······················ 07.Mon.P1.29 Küpper, Jochen ··························· 09.Wed.P3.37 Kato, Reizo ·································· 08.Tue.P2.35 Kitajima, Masahiro ······················ 07.Mon.P1.42 Kurahashi, Naoya ···························· 07.Mon.B.7 Kato, Takeo ·································· 08.Tue.P2.33 Kitajima, Masahiro ······················ 09.Wed.P3.29 Kuramochi, Hikaru ······················· 08.Tue.P2.26 Kato, Tsuyoshi ···························· 07.Mon.P1.16 Kitamura, Tsuyoshi ······················ 08.Tue.P2.51 Kuramochi, Hikaru ·························· 10.Thu.D.5 Katsumura, Shigeo ······················ 09.Wed.P3.25 Kitano, Kenta ······························ 07.Mon.P1.53 Kuramoto, Yoshiyuki ····················· 08.Tue.P2.51 Kausch-Busies, Nina ························ 08.Tue.E.7 Kitzler, Markus ······························· 08.Tue.P2.3 Kurihara, Takayuki ······················· 08.Tue.P2.33 Kawakami, Yohei ························· 07.Mon.P1.40 Kitzler, Markus ····························· 08.Tue.P2.16 Kusa, Fumiya ··································· 08.Tue.B.4

INDEX Kawakami, Yohei ························· 09.Wed.P3.40 Kitzler, Markus ································ 09.Wed.C.5 Kusaba, Miyuki ··························· 09.Wed.P3.54 Kawasaki, Masashi ························· 07.Mon.D.6 Kitzler, Markus ································ 09.Wed.C.6 Kuwata-Gonokami, Makoto ·············· 10.Thu.B.7 Kawasaki, Tomohiro ···················· 07.Mon.P1.32 Kling, Matthias ································ 07.Mon.B.4 Kwon, Oh-Hoon ······························· 09.Wed.E.6 Kawato, Sakae ····························· 08.Tue.P2.50 Klingebiel, Sandro ··························· 09.Wed.B.3 Lahme, Stefan ································ 09.Wed.C.1 Kayanuma, Yosuke ······················ 07.Mon.P1.39 Knut, Ronny ····································· 10.Thu.B.1 Lan, Pengfei ·································· 07.Mon.P1.7 Kayanuma, Yosuke ······················ 09.Wed.P3.38 Kobayashi, Takayoshi ······················· 08.Tue.D.2 Lan, Pengfei ································· 08.Tue.P2.49 Kazansky, Andrey ·························· 09.Wed.P3.5 Kobayashi, Takayoshi ··················· 08.Tue.P2.31 Lancis, Jesus ······························ 07.Mon.P1.11 Keathley, Phillip D. ······················ 09.Wed.P3.37 Kobayashi, Yohei ························· 07.Mon.P1.34 Lancis, Jesus ······························· 08.Tue.P2.60 Keiber, Sabine ·································· 10.Thu.C.6 Kobayashi, Yohei ·························· 08.Tue.P2.51 Landsman, Alexandra S. ··············· 08.Tue.P2.10 Keilmann, Fritz ································· 10.Thu.C.3 Koch, Markus ································· 08.Tue.P2.6 Langdon, Benjamin ························· 07.Mon.A.2 Keimer, Bernhard ···························· 07.Mon.D.1 Koch, Stephan W. ···························· 07.Mon.C.1 Lange, Christoph ······························ 10.Thu.A.3 Keimer, Bernhard ························ 07.Mon.P1.47 Koch, Stephan W. ····························· 10.Thu.A.3 Lange, Holger ·································· 08.Tue.E.2 Keinan, Sharon ··························· 09.Wed.P3.16 Koeppe, Benjamin ······················· 09.Wed.P3.16 Langer, Fabian ································· 10.Thu.A.3 Keister, Ellen ··································· 09.Wed.E.2 Koga, Ryosuke ································ 09.Wed.D.5 Lanzani, Guglielmo ······················ 08.Tue.P2.34 Keller, Ursula ···································· 08.Tue.A.6 Kohmoto, Toshiro ························ 07.Mon.P1.38 Laptev, Alexej ······························ 07.Mon.P1.41 Keller, Ursula ································ 08.Tue.P2.10 Kohmoto, Toshiro ························ 09.Wed.P3.32 Lasorne, Benjamin ······················· 08.Tue.P2.20 Keller, Ursula ································ 08.Tue.P2.40 Koirala, Nikesh ································ 09.Wed.B.7 Lassonde, Philippe ··························· 08.Tue.D.3 Keller, Ursula ································ 08.Tue.P2.56 Kolobov, Alexander ······················· 08.Tue.P2.43 Laulhe, Claire ·································· 07.Mon.D.5 Keller, Ursula ··································· 09.Wed.C.7 Kolobov, Alexander ······················ 09.Wed.P3.34 Laurent, Guillaume M. ························ 11.Fri.B.4 Keller, Ursula ······························· 09.Wed.P3.59 Konar, Arkaprabha ························ 08.Tue.P2.23 Lauvergnat, David ························ 08.Tue.P2.20 Kelloway, Donald ···························· 09.Wed.D.7 Kono, Hirohiko ···························· 07.Mon.P1.21 Le, Anh Thu ····································· 07.Mon.A.5 Kerner, Christian ·························· 08.Tue.P2.28 Kono, Hirohiko ···························· 07.Mon.P1.25 Le, Anh Thu ····································· 09.Wed.C.3 Keskin, Sercan ····························· 08.Tue.P2.35 Kono, Hirohiko ································ 09.Wed.D.5 Le Tacon, Mathieu ··························· 07.Mon.D.1 Kﬁ r, Ofer ·········································· 10.Thu.B.1 Koppens, Frank ······························· 09.Wed.B.4 Le Tacon, Mathieu ······················· 07.Mon.P1.47 Khademi, Zane ···························· 07.Mon.P1.24 Kornilov, Oleg ··································· 08.Tue.A.2 Lebedev, Michael V. ····················· 09.Wed.P3.31 Khalil, Munira ·································· 09.Wed.A.3 Korsunsky, Alexander ······················ 09.Wed.E.1 Lee, Jae Hyuk ································· 09.Wed.D.2 Khalil, Munira ·································· 09.Wed.D.3 Koseki, Shiro ······························· 07.Mon.P1.25 Lee, Jaedong ······························· 08.Tue.P2.39 68 AUTHORS’ INDEX ▶

Lee, Kwang Jin ···························· 08.Tue.P2.29 Lucchini, Matteo ······························ 08.Tue.A.6 Masaki, Yuta ······························· 09.Wed.P3.54 Lee, Taegon ································ 09.Wed.P3.13 Lucchini, Matteo ·························· 08.Tue.P2.40 Mashiko, Hiroki ··························· 09.Wed.P3.55 Lee, Wei-Sheng ······························ 07.Mon.D.2 Lücking, Fabian ··························· 08.Tue.P2.52 Mathevet, Fabrice ························ 08.Tue.P2.29 Lee, Wei-Sheng ······························ 07.Mon.D.4 Lücking, Fabian ·························· 09.Wed.P3.52 Matsubara, Shinichi ···················· 07.Mon.P1.50 Lee, Yun-Shik ······························ 07.Mon.P1.30 Ludwig, André ·································· 08.Tue.A.6 Matsuda, Akitaka ··························· 08.Tue.P2.4 Légaré, François ····························· 07.Mon.B.2 Ludwigs, Sabine ························· 09.Wed.P3.26 Matsuda, Akitaka ··························· 08.Tue.P2.5 Légaré, François ··························· 07.Mon.P1.5 Luebcke, Andrea ····························· 07.Mon.D.5 Matsuda, Akitaka ························· 08.Tue.P2.18 Légaré, François ······························ 08.Tue.D.3 Luer, Larry ······································· 08.Tue.C.5 Matsuda, Akitaka ························ 09.Wed.P3.23 Légaré, François ························· 09.Wed.P3.49 Luning, Jan ································· 09.Wed.P3.35 Matsuki, Takashi ····························· 09.Wed.E.3 Lehner, Florian ···························· 09.Wed.P3.11 Luo, Chih Wei ······························ 07.Mon.P1.43 Matsumoto, Yoshiyasu ····················· 08.Tue.E.5 Leitenstorfer, Alfred ························· 09.Wed.B.1 Luo, Chih Wei ··································· 08.Tue.D.1 Matsunaga, Ryusuke ······················· 10.Thu.A.1 Leitenstorfer, Alfred ·························· 10.Thu.A.5 Luo, Chih Wei ······························· 08.Tue.P2.31 Matsunami, Kenji ························ 07.Mon.P1.46 Lemke, Henrik ································ 07.Mon.D.1 Luo, Yuanson ······························ 07.Mon.P1.41 Matsunami, Kenji ···························· 09.Wed.D.5 Lemke, Henrik ································ 07.Mon.D.6 Luponosov, Yuriy N. ·························· 08.Tue.E.7 Matsunami, Kenji ·························· 09.Wed.P3.3 Lemke, Henrik ································ 09.Wed.E.1 Lütgens, Matthias ······················· 07.Mon.P1.14 Matsunami, Kenji ·························· 09.Wed.P3.5 Léonard, Jérémie ························ 09.Wed.P3.12 Luu, Tran Trung ································ 10.Thu.B.4 Matyschok, Jan ·························· 09.Wed.P3.53 Lewis, Nicholas ································ 08.Tue.C.2 Lynch, Michael ································ 09.Wed.A.3 Maurer, Faffael ······························· 08.Tue.P2.7 Li, Guihua ····································· 07.Mon.P1.2 Madsen, Lars B. ···························· 07.Mon.P1.9 Mayer, Benedikt W. ······················· 08.Tue.P2.56 Li, Hebin ········································· 07.Mon.C.1 Madsen, Lars B. ····························· 08.Tue.P2.9 Mayer, Bernhard ····························· 09.Wed.B.1 Li, Helong ····································· 07.Mon.P1.2 Maekawa, Keisuke ······················ 07.Mon.P1.42 Mayer, Bernhard ······························ 10.Thu.A.5 Li, Jialin ······································ 09.Wed.P3.15 Maerz, Benjamin ····························· 09.Wed.D.4 Mayer, Jan ·································· 07.Mon.P1.41 Libbey, Stephen B. ·························· 09.Wed.E.2 Mahler, Benoit ···································· 11.Fri.A.3 Mayr, Herbert ·································· 07.Mon.E.5 Liekhus-Schmaltz, Chelsea ················ 11.Fri.B.6 Mai, Sebastian ································ 10.Thu.D.1 Mazur, Kamila ······························ 08.Tue.P2.21 Lienau, Christoph ····························· 10.Thu.B.5 Mailam, Anand ································ 09.Wed.D.5 Mazur, Leszek ······························ 08.Tue.P2.29 Lifshitz, Efrat ··································· 07.Mon.C.6 Maity, Partha ······························· 07.Mon.P1.31 Meier, Torsten ·································· 10.Thu.A.3 Lim, Manho ································· 09.Wed.P3.13 Maiuri, Margherita ······················ 07.Mon.P1.52 Mendoza-Yero, Omel ··················· 07.Mon.P1.11 Lin, Chii Dong ································· 07.Mon.A.5 Maiuri, Margherita ··························· 08.Tue.C.5 Mendoza-Yero, Omel ···················· 08.Tue.P2.60 Lin, Chii Dong ·································· 08.Tue.A.2 Maiuri, Margherita ·························· 09.Wed.A.1 Merklein, Moritz ·························· 07.Mon.P1.41 Lin, Chii Dong ································· 09.Wed.C.3 Major, Balazs ······························ 07.Mon.P1.37 Merschjann, Christoph ················ 09.Wed.P3.39 Lin, Jiunn-Yuan ···························· 08.Tue.P2.31 Makida, Ayumu ···························· 08.Tue.P2.14 Merschjohann, Fabian ······················ 10.Thu.B.3 Link, Stefan ································· 08.Tue.P2.48 Makino, Kotaro ···························· 09.Wed.P3.34 Messerschmidt, Marc ····················· 09.Wed.E.1 Litvinyuk, Igor ······························ 08.Tue.P2.17 Makise, Kazumasa ··························· 10.Thu.A.1 Messmer, Andreas T. ······················· 09.Wed.A.5 Liu, Chien-Nam ······························ 08.Tue.P2.4 Malevich, Pavel ······························ 08.Tue.P2.7 Meyer, Hans-Dieter ······················ 08.Tue.P2.20 Liu, Haiyun ·································· 07.Mon.P1.35 Malevich, Pavel ···························· 08.Tue.P2.57 Michelmann, Jeff ························ 09.Wed.P3.11 Liu, Lai Chung ······························ 08.Tue.P2.37 Malicki, Michal ···························· 07.Mon.P1.24 Mics, Zoltan ···································· 09.Wed.B.4 Liu, Lai Chung ································· 09.Wed.D.7 Mancini, Giulia Fulvia ·················· 09.Wed.P3.50 Midorikawa, Katsumi ······················ 07.Mon.A.1 INDEX Liu, Lai Chung ····························· 09.Wed.P3.36 Mancuso, Christopher A. ················· 07.Mon.A.2 Midorikawa, Katsumi ···················· 07.Mon.P1.6 Liu, Li ········································· 09.Wed.P3.26 Maneshi, Samansa ······················ 08.Tue.P2.53 Midorikawa, Katsumi ·················· 07.Mon.P1.50 Liu, Wei ··········································· 09.Wed.A.6 Maneshi, Samansa ························· 09.Wed.A.4 Midorikawa, Katsumi ··················· 08.Tue.P2.16 Liu, Weiwei ··································· 09.Wed.P3.1 Mankowsky, Roman ························ 07.Mon.D.1 Midorikawa, Katsumi ··················· 08.Tue.P2.49 Liu, XiaoJing ··································· 09.Wed.D.5 Mankowsky, Roman ························ 07.Mon.D.4 Midorikawa, Katsumi ···················· 09.Wed.P3.4 Liu, XiaoJing ································· 09.Wed.P3.3 Manzoni, Cristian ························ 07.Mon.P1.36 Midorikawa, Katsumi ···················· 09.Wed.P3.7 Liu, Xiaojun ····································· 09.Wed.C.6 Manzoni, Cristian ························ 07.Mon.P1.52 Mikhaylovskiy, Rostislav ·············· 07.Mon.P1.48 Liu, Yi-Sheng ······························ 09.Wed.P3.14 Manzoni, Cristian ························ 07.Mon.P1.55 Miki, Takeshi ···································· 08.Tue.C.3 Lochbrunner, Stefan ························ 07.Mon.B.6 Manzoni, Cristian ························· 08.Tue.P2.58 Miller, Dwayne ····························· 08.Tue.P2.22 Lochbrunner, Stefan ···················· 07.Mon.P1.14 Manzoni, Cristian ···························· 09.Wed.A.1 Miller, Dwayne ····························· 08.Tue.P2.37 Lochbrunner, Stefan ···················· 09.Wed.P3.39 Manzoni, Cristian ····························· 10.Thu.B.5 Miller, Dwayne ································ 09.Wed.A.4 Locher, Reto ································· 08.Tue.P2.40 Marangoni, Marko ·························· 08.Tue.P2.7 Miller, Dwayne ································ 09.Wed.D.7 Loew, Toshinao ······························· 07.Mon.D.1 Marangos, Jonathan P. ···················· 07.Mon.A.4 Miller, Dwayne ···························· 09.Wed.P3.36 Loew, Toshinao ··························· 07.Mon.P1.47 Marangos, Jonathan P. ·················· 09.Wed.P3.3 Miller, R. J. Dwayne ····················· 08.Tue.P2.35 Loh, Zhi-Heng ····························· 09.Wed.P3.15 March, Anne Marie ·························· 09.Wed.D.1 Miller, R. J. Dwayne ····················· 08.Tue.P2.53 Lombosi, Csaba ······························ 09.Wed.B.3 Marder, Seth ······························· 07.Mon.P1.24 Miller, Reginald ································ 08.Tue.B.6 Longhi, Stefano ···························· 08.Tue.P2.45 Marek, Marie ··································· 08.Tue.C.3 Miller, Timothy A. ····························· 07.Mon.D.7 Lötstedt, Erik ································· 08.Tue.P2.3 Mariager, Simon ······························ 07.Mon.D.1 Milne, Christopher J. ······················· 09.Wed.D.1 Lötstedt, Erik ······························· 08.Tue.P2.16 Mariager, Simon ······························ 07.Mon.D.5 Minami, Yasuo ···························· 07.Mon.P1.29 Loukianov, Anton ························· 09.Wed.P3.48 Mariager, Simon ······························ 07.Mon.D.6 Minami, Yasuo ···························· 07.Mon.P1.42 Lovrincic, Robert ······························ 08.Tue.E.3 Marini, Andrea ···························· 07.Mon.P1.36 Minami, Yasuo ····························· 08.Tue.P2.38 Lozovoy, Vadim V. ························· 08.Tue.P2.23 Marquetand, Philipp ························ 10.Thu.D.1 Minami, Yasuo ···························· 09.Wed.P3.29 Lu, Cheng ···································· 08.Tue.P2.37 Martin, Fernando G. ························· 08.Tue.A.3 Minguez-Vega, Glaldys ················ 07.Mon.P1.11 Lu, Cheng ······································· 09.Wed.D.7 Martin, Fernando G. ························· 08.Tue.A.5 Minguez-Vega, Glaldys ················· 08.Tue.P2.60 Lu, Cheng ··································· 09.Wed.P3.36 Martínez, Todd J. ····························· 07.Mon.B.5 Minitti, Michael ······························· 07.Mon.D.1 Lu, Peixiang ·································· 07.Mon.P1.7 Maruta, Satoshi ·························· 07.Mon.P1.12 Minitti, Michael ······························· 07.Mon.D.4 Lu, Peixiang ···································· 09.Wed.C.6 Marvel, Robert E. ····························· 10.Thu.A.5 Miron, Catalin ································· 09.Wed.D.5 Lucchese, Robert R. ······················ 07.Mon.P1.9 Marx, Alexander ··························· 08.Tue.P2.35 Miron, Catalin ······························· 09.Wed.P3.3 Lucchese, Robert R. ······················· 08.Tue.P2.9 Masaki, Yuta ···································· 08.Tue.B.2 Miron, Catalin ······························· 09.Wed.P3.5 69 ▶ AUTHORS’ INDEX

Misawa, Kazuhiko ··························· 07.Mon.B.7 Murata, Kei ········································ 11.Fri.A.7 Nisoli, Mauro ··································· 08.Tue.A.3 Misawa, Kazuhiko ···························· 10.Thu.B.7 Murnane, Margaret ························· 07.Mon.A.2 Nisoli, Mauro ······························· 08.Tue.P2.52 Misawa, Kazuhiko ···························· 10.Thu.C.1 Murnane, Margaret ····················· 07.Mon.P1.18 Nisoli, Mauro ······························ 09.Wed.P3.51 Misochko, Oleg ··························· 09.Wed.P3.31 Murnane, Margaret ····················· 07.Mon.P1.54 Noguchi, Tomohiro ·························· 09.Wed.E.3 Mitrano, Matteo ··························· 08.Tue.P2.48 Murnane, Margaret ························· 09.Wed.E.2 Noji, Tomoyasu ································ 08.Tue.C.6 Mitrofanov, Kirill ··························· 08.Tue.P2.43 Murnane, Margaret ·························· 10.Thu.B.1 Nomura, Mitsushiro ····················· 08.Tue.P2.35 Mitrofanov, Kirill ·························· 09.Wed.P3.34 Nabekawa, Yasuo ·························· 07.Mon.P1.6 Nomura, Yutaka ·························· 07.Mon.P1.43 Miura, Shun ································ 07.Mon.P1.10 Nabekawa, Yasuo ·························· 09.Wed.P3.4 Nomura, Yutaka ······························· 08.Tue.D.1 Miyamoto, Mitsuhiro ··················· 07.Mon.P1.13 Nabekawa, Yasuo ·························· 09.Wed.P3.7 Nomura, Yutaka ··························· 08.Tue.P2.50 Miyamoto, Tatsuya ·························· 09.Wed.B.6 Nagao, Tadaaki ··························· 07.Mon.P1.29 Norimatsu, Katsura ····················· 07.Mon.P1.44 Miyasaka, Hiroshi ······················· 07.Mon.P1.19 Nagao, Tadaaki ··························· 09.Wed.P3.29 Norimatsu, Katsura ····················· 09.Wed.P3.38 Miyasaka, Hiroshi ···························· 08.Tue.C.6 Nagasawa, Yutaka ······················ 07.Mon.P1.19 Norris, Theodore B. ····················· 07.Mon.P1.30 Miyasaka, Hiroshi ······················· 09.Wed.P3.19 Nagasawa, Yutaka ··························· 08.Tue.C.6 Nosenko, Yevgeniy ······················· 08.Tue.P2.28 Miyata, Kiyoshi ································ 08.Tue.E.5 Nagasawa, Yutaka ······················ 09.Wed.P3.19 Nova, Tobia ································· 07.Mon.P1.48 Mizoguchi, Kohji ······························ 07.Mon.C.4 Nagasono, Mitsuru ······················ 07.Mon.P1.46 Nuernberger, Patrick ······················· 07.Mon.B.3 Mizokuchi, Raisei ···························· 09.Wed.E.3 Nagasono, Mitsuru ························· 08.Tue.P2.4 Nuernberger, Patrick ····················· 07.Mon.P1.1 Mizuno, Misao ···························· 07.Mon.P1.13 Nagasono, Mitsuru ························· 08.Tue.P2.5 O’Keeffe, Patrick ··························· 09.Wed.P3.5 Mizutani, Naoto ································ 08.Tue.C.6 Nagasono, Mitsuru ························ 09.Wed.P3.5 Oba, Wataru ································· 08.Tue.P2.38 Mizutani, Yasuhisa ······················ 07.Mon.P1.13 Nagata, Tomoko ··························· 08.Tue.P2.41 Obara, Yuki ····································· 07.Mon.B.7 Molesky, Sean ································· 08.Tue.B.6 Nagaya, Kiyonobu ······················· 07.Mon.P1.46 Obara, Yuki ······································ 10.Thu.C.1 Molle, Alessandro ························ 09.Wed.P3.42 Nagaya, Kiyonobu ··························· 09.Wed.D.5 Oda, Shunri ····································· 09.Wed.E.3 Møller, Klaus B. ······························· 07.Mon.B.5 Nagaya, Kiyonobu ························· 09.Wed.P3.3 Oelmann, Jannis ······························ 10.Thu.A.5 Monahan, Daniele ························ 08.Tue.P2.24 Nagaya, Kiyonobu ························· 09.Wed.P3.5 Oesterling, Sven ······························ 09.Wed.D.4 Monahan, Daniele ······················· 09.Wed.P3.24 Nagy, Tamas ···································· 10.Thu.C.5 Ogawa, Kanade ··························· 07.Mon.P1.50 Mondal, Subhendu ······················ 07.Mon.P1.46 Naito, Yota ··································· 09.Wed.P3.40 Ogawa, Kanade ··························· 07.Mon.P1.51 Mondal, Subhendu ·························· 09.Wed.D.5 Naito, Yota ··································· 09.Wed.P3.41 Ogi, Yoshihiro ·································· 07.Mon.B.7 Mondal, Subhendu ························ 09.Wed.P3.3 Nakai, Katsunori ························· 07.Mon.P1.10 Ogilvie, Jennifer P. ···························· 08.Tue.C.1 Mondal, Subhendu ························ 09.Wed.P3.5 Nakai, Katsunori ·························· 08.Tue.P2.25 Ogilvie, Jennifer P. ······················· 09.Wed.P3.48 Monoszlai, Balazs ··························· 09.Wed.B.2 Nakajima, Makoto ························ 08.Tue.P2.33 Oguri, Katsuya ···························· 09.Wed.P3.55 Mootz, Martin ································· 07.Mon.C.1 Nakamura, Kazutaka ··················· 07.Mon.P1.44 Oh, Juyeong ································ 07.Mon.P1.30 Morgan, Sarah ··································· 11.Fri.A.4 Nakamura, Kazutaka ··················· 09.Wed.P3.38 Oh, Seongshik ································ 09.Wed.B.7 Morgner, Uwe ····························· 09.Wed.P3.53 Nakamura, Masao ··························· 07.Mon.D.6 Ohmura, Satoshi ····························· 09.Wed.D.5 Morgner, Uwe ·································· 10.Thu.C.5 Nakamura, Ryosuke ····················· 08.Tue.P2.12 Ohshima, Yasuhiro ······················ 07.Mon.P1.15 Morimoto, Takeshi ··························· 09.Wed.B.6 Nakamura, Takashi ····················· 07.Mon.P1.21 Ohta, Kaoru ····································· 07.Mon.E.6 Morimoto, Yuya ······························ 08.Tue.P2.2 Nakano, Motoyoshi ······················· 07.Mon.P1.8 Ohta, Kaoru ································· 07.Mon.P1.23 Morimoto, Yuya ······························· 09.Wed.C.2 Nakano, Takashi ·························· 09.Wed.P3.34 Okamoto, Hiromi ····························· 09.Wed.E.4 Morishita, Toru ······························ 07.Mon.P1.9 Nambu, Shohei ··························· 07.Mon.P1.19 Okamoto, Hiroshi ···························· 09.Wed.B.6 Morishita, Toru ······························· 08.Tue.P2.4 Nango, Mamoru ······························· 08.Tue.C.7 Okayasu, Yuichi ··························· 07.Mon.P1.50

INDEX Morishita, Toru ······························· 08.Tue.P2.9 Narushima, Tetsuya ························ 09.Wed.E.4 Okimoto, Yoichi ···························· 08.Tue.P2.35 Morita, Ryuji ···································· 08.Tue.D.5 Nasalevich, Maxim ······················· 08.Tue.P2.21 Okino, Tomoya ······························ 07.Mon.P1.6 Moriyasu, Takeshi ······················· 07.Mon.P1.38 Natan, Adi ····································· 09.Wed.P3.8 Okino, Tomoya ······························ 09.Wed.P3.4 Moriyasu, Takeshi ······················· 09.Wed.P3.32 Neb, Sergej ······································ 10.Thu.B.3 Okino, Tomoya ······························ 09.Wed.P3.7 Moses, Jeffrey ································· 08.Tue.D.6 Negro, Matteo ····························· 09.Wed.P3.49 Oksenhendler, Thomas ················· 08.Tue.P2.52 Moshammer, Robert ························ 09.Wed.C.3 Negro, Matteo ···································· 11.Fri.B.1 Oksenhendler, Thomas ················ 09.Wed.P3.51 Motomura, Koji ··························· 07.Mon.P1.46 Negro, Matteo ···································· 11.Fri.B.3 Okumura, Satoshi ······················· 09.Wed.P3.25 Motomura, Koji ······························· 09.Wed.D.5 Nelson, Keith ······························ 09.Wed.P3.43 Okunishi, Misaki ··························· 07.Mon.P1.9 Motomura, Koji ····························· 09.Wed.P3.3 Nembach, Hans ······························· 10.Thu.B.1 Okunishi, Misaki ···························· 08.Tue.P2.9 Motomura, Koji ····························· 09.Wed.P3.5 Neppl, Stefan ······························ 09.Wed.P3.14 Oliver, Thomas ································· 08.Tue.C.2 Motzkus, Marcus ····························· 08.Tue.C.3 Neppl, Stefan ··································· 10.Thu.B.2 Olivucci, Massimo ······················· 09.Wed.P3.12 Motzkus, Marcus ····························· 08.Tue.E.6 Ni, Jielei ········································ 07.Mon.P1.2 Ollmann, Zoltan ······························ 09.Wed.B.3 Moulet, Antoine ································ 10.Thu.B.4 Nibbering, Erik T.J. ······················ 09.Wed.P3.16 Onda, Ken ···································· 08.Tue.P2.35 Mücke, Oliver D. ························· 07.Mon.P1.55 Nibbering, Erik T.J. ····························· 11.Fri.A.1 Onda, Ken ······································· 09.Wed.E.3 Mücke, Oliver D. ························· 09.Wed.P3.37 Nicolas, Christophe ························· 09.Wed.D.5 Onda, Ken ·········································· 11.Fri.A.7 Mücke, Oliver D. ························· 09.Wed.P3.60 Nicoletti, Daniele ························· 07.Mon.P1.47 Oohata, Goro ··································· 07.Mon.C.4 Mukai, Yu ········································ 09.Wed.B.5 Nie, Bai ······································· 07.Mon.P1.59 Orenstein, Gal ···································· 11.Fri.B.5 Mukamel, Shaul ······························ 09.Wed.A.2 Nie, Zhaogang ···························· 09.Wed.P3.15 Oriana, Aurelio ································ 09.Wed.A.1 Mukamel, Shaul ······························ 09.Wed.D.6 Nihonyanagi, Satoshi ·················· 07.Mon.P1.27 Oshima, Takashi ·························· 07.Mon.P1.50 Mukamel, Shaul ·························· 09.Wed.P3.22 Niikura, Hiromichi ························· 09.Wed.P3.6 Ossiander, Marcus ··························· 10.Thu.B.2 Mukuta, Tatsuhiko ······························ 11.Fri.A.7 Niitsu, Naoyuki ···························· 07.Mon.P1.21 Osterwalder, Jürg ························· 08.Tue.P2.40 Müllen, Klaus ·································· 09.Wed.B.4 Nillon, Julien ······························· 09.Wed.P3.57 Otake, Yuji ··································· 07.Mon.P1.50 Müller, Melanie ································ 08.Tue.B.1 Nishimoto, Tomohisa ··················· 09.Wed.P3.32 Otobe, Tomohito ······························ 07.Mon.C.5 Müller, Norbert ································· 10.Thu.B.3 Nishio, Masatoshi ························ 08.Tue.P2.50 Otobe, Tomohito ···························· 09.Wed.P3.9 Müller-Werkmeister, Henrike ··········· 10.Thu.D.6 Nishiyama, Toshiyuki ··················· 07.Mon.P1.46 Otsu, Toshio ································ 07.Mon.P1.34 Muramastu, Masayasu ················ 09.Wed.P3.19 Nishiyama, Yoshio ··························· 09.Wed.E.4 Owada, Shigeki ··························· 07.Mon.P1.50 Murata, Hiroyuki ·························· 08.Tue.P2.47 Nisoli, Mauro ··································· 08.Tue.A.2 Owada, Shigeki ··························· 07.Mon.P1.51 70 AUTHORS’ INDEX ▶

Ozawa, Akira ······························· 07.Mon.P1.34 Prokhorenko, Valentyn ················· 08.Tue.P2.53 Röttger, Katharina ······················· 07.Mon.P1.20 Paarmann, Alexander ······················· 08.Tue.B.1 Prokhorenko, Valentyn ···················· 09.Wed.A.4 Röttger, Katharina ··························· 10.Thu.D.2 Paasch-Colberg, Tim ························ 10.Thu.B.6 Pruneri, Valerio ······························· 07.Mon.D.7 Rouzée, Arnaud ····························· 09.Wed.P3.2 Paasch-Colberg, Tim ························ 10.Thu.C.6 Psciuk, Brian T. ··························· 09.Wed.P3.16 Rude, Miquel ·································· 07.Mon.D.7 Pabst, Stefan ··································· 10.Thu.B.4 Pshenichnikov, Maxim S. ·················· 08.Tue.E.4 Rudek, Benedikt ··························· 09.Wed.P3.3 Pabst, Stefan ····································· 11.Fri.B.3 Pshenichnikov, Maxim S. ·················· 08.Tue.E.7 Rudenko, Artem ······························ 09.Wed.D.5 Palacios, Alicia ································· 08.Tue.A.3 Pshenichnikov, Maxim S. ·············· 08.Tue.P2.27 Ruff, Adrian ································· 09.Wed.P3.26 Palacios, Alicia ································· 08.Tue.A.5 Pug¡zlys, Audrius ···························· 07.Mon.A.3 Ruhman, Sanford ···························· 07.Mon.C.6 Pálfalvi, László ································ 09.Wed.B.3 Pug¡zlys, Audrius ··························· 08.Tue.P2.7 Ruhman, Sanford ························· 08.Tue.P2.13 Palm, Brett B. ······························ 07.Mon.P1.18 Pug¡zlys, Audrius ························· 08.Tue.P2.57 Ruhman, Sanford ························ 09.Wed.P3.28 Palm, Brett B. ·································· 09.Wed.E.2 Pugzlys, Audrius ····························· 07.Mon.A.4 Rupp, Fabian ································ 08.Tue.P2.28 Pan, Jie ············································ 08.Tue.C.1 Pullen, Michael G. ··························· 09.Wed.C.3 Sabbar, Mazyar ······························· 09.Wed.C.7 Pan, Jie ······································· 09.Wed.P3.48 Pullerits, Tonu ·································· 08.Tue.E.1 Sachs, Hanan ································· 07.Mon.C.6 Papanikolas, John ··························· 09.Wed.E.5 Puppin, Michele ·························· 09.Wed.P3.53 Sagae, Yuto ································· 07.Mon.P1.40 Paraschuk, Dmitry ··························· 08.Tue.E.7 Putnam, William ······························· 08.Tue.B.3 Sagae, Yuto ·································· 08.Tue.P2.41 Park, Doo Jae ·································· 10.Thu.B.5 Radovic, Milan ································ 07.Mon.D.6 Sagae, Yuto ································· 09.Wed.P3.40 Park, Samuel ······························· 08.Tue.P2.44 Rao, Akshay ···································· 07.Mon.C.7 Sağlam Özge ··································· 10.Thu.C.6 Park, Seongchul ·························· 09.Wed.P3.13 Rao, Akshay ····································· 08.Tue.E.3 Saiki, Toshiharu ··························· 08.Tue.P2.38 Parkin, Stuart S. ·························· 09.Wed.P3.44 Rao, Akshay ······································· 11.Fri.A.4 Saito, Norio ································· 07.Mon.P1.46 Parvez, Khaled ································ 09.Wed.B.4 Rathje, Tim ····································· 09.Wed.C.5 Saito, Norio ··································· 09.Wed.P3.5 Pascher, Tobjorn ······························· 08.Tue.E.1 Ravy, Sylvain ··································· 07.Mon.D.5 Saito, Yuta ··································· 09.Wed.P3.34 Pashkin, Alexej ································ 09.Wed.B.1 Razdolski, Ilya ····························· 07.Mon.P1.48 Sakaguchi, Kazuhiko ··················· 09.Wed.P3.25 Pashkin, Alexej ································· 10.Thu.A.5 Razskazovskaya, Olga ······················ 10.Thu.C.6 Sakai, Shunsuke ······························ 08.Tue.C.7 Paulus, Gerhard G. ··························· 08.Tue.D.7 Reduzzi, Maurizio ····························· 08.Tue.A.2 Sakai, Tsukasa ···························· 07.Mon.P1.46 Paulus, Gerhard G. ························· 08.Tue.P2.3 Reguero, Mar ······························· 08.Tue.P2.20 Sakai, Tsukasa ································ 09.Wed.D.5 Paulus, Gerhard G. ·························· 09.Wed.C.5 Rehault, Julien ···························· 07.Mon.P1.52 Sakai, Tsukasa ······························ 09.Wed.P3.3 Pedatzur, Oren ··································· 11.Fri.B.5 Rehault, Julien ································ 09.Wed.A.1 Sakai, Tsukasa ······························ 09.Wed.P3.5 Peli, Simone ································ 07.Mon.P1.33 Reimann, Klaus ···························· 08.Tue.P2.46 Salmeron, Miquel ························ 09.Wed.P3.14 Penfold, Tom ··································· 09.Wed.D.1 Rettig, Laurenz ······························· 07.Mon.D.6 Samant, Mahesh G. ····················· 09.Wed.P3.44 Pensack, Ryan ··································· 11.Fri.A.3 Reuss, Andreas J. ······················· 09.Wed.P3.27 Samoylova, Elena ···························· 09.Wed.D.4 Perez Vizcaino, Jorge ··················· 08.Tue.P2.60 Reuter, Dirk ····································· 07.Mon.C.3 Samwer, Konrad ························· 07.Mon.P1.41 Pérez Vizcaíno, Jorge ·················· 07.Mon.P1.11 Ribierre, Jean-Charles ················· 08.Tue.P2.29 Sanderson, Joseph ························· 07.Mon.B.2 Perveaux, Aurelie ························· 08.Tue.P2.20 Richards, Gethin H. ·························· 08.Tue.C.4 Sang, Robert ································ 08.Tue.P2.17 Petek, Hrvoje ·································· 07.Mon.C.2 Richter, Martin ································ 10.Thu.D.1 Sangalli, Davide ·························· 07.Mon.P1.36 Petersen, Jesse ·························· 07.Mon.P1.35 Riedle, Eberhard ····························· 07.Mon.E.5 Sangwan, Sim ································ 09.Wed.B.7 Petrov, George M. ···························· 09.Wed.E.2 Riedle, Eberhard ························· 07.Mon.P1.56 Sansone, Giuseppe ·························· 08.Tue.A.2 INDEX Petrovic, Vladimir ······························· 11.Fri.B.6 Riedle, Eberhard ······························ 08.Tue.D.4 Sansone, Giuseppe ······················ 08.Tue.P2.52 Pfeifer, Thomas ································ 08.Tue.A.1 Riehn, Christoph ·························· 08.Tue.P2.28 Sansone, Giuseppe ····················· 09.Wed.P3.51 Pfeiffer, Walter ···························· 09.Wed.P3.47 Riemensberger, Johann ··················· 10.Thu.B.2 Santomauro, Fabio ·························· 09.Wed.D.1 Pfeiffer, Walter ································· 10.Thu.B.3 Ristau, Detlef ··································· 10.Thu.C.5 Santra, Robin ································ 09.Wed.P3.3 Phillips, Christopher R. ················· 08.Tue.P2.56 Ristow, Oliver ······························ 07.Mon.P1.41 Santra, Robin ····································· 11.Fri.B.3 Picchiotti, Alessandra ······················ 09.Wed.A.4 Rittmann, Jochen ···························· 09.Wed.D.1 Saraceno, Clara J. ······················· 09.Wed.P3.59 Pichugin, Kostyantyn ···················· 08.Tue.P2.35 Robert, Aymeric ······························ 07.Mon.D.6 Sasagawa, Takao ························ 07.Mon.P1.44 Piglosiewicz, Björn ··························· 10.Thu.B.5 Robert, Emmanuel ························ 09.Wed.P3.3 Sasaki, Takahiko ························· 07.Mon.P1.40 Pilles, Bert M. ································· 10.Thu.D.4 Robin, Jörg ······································ 10.Thu.B.5 Sasaki, Takahiko ·························· 08.Tue.P2.41 Pinion, Christopher ·························· 09.Wed.E.5 Robinson, Ian ·································· 09.Wed.E.1 Sasaki, Takahiko ························· 09.Wed.P3.40 Plaja, Luis ······································· 07.Mon.A.2 Robinson, Joe ································· 07.Mon.D.1 Sato, Kenji ·································· 07.Mon.P1.42 Poletto, Luca ···································· 08.Tue.A.2 Robinson, Joe ································· 07.Mon.D.4 Sato, Masaaki ·································· 10.Thu.B.7 Poletto, Luca ···································· 08.Tue.A.3 Rode, Michal F. ··························· 09.Wed.P3.20 Sato, Motoki ···································· 08.Tue.A.4 Polli, Dario ······································· 08.Tue.C.5 Rodin, Aleksandr ······························ 10.Thu.C.3 Sato, Shunsuke A. ··························· 07.Mon.C.5 Polli, Dario ······································ 09.Wed.A.1 Rodríguez-Fernández, Jessica ···· 09.Wed.P3.33 Sato, Takahiro ····························· 07.Mon.P1.50 Ponomarenko, Sergei A. ··················· 08.Tue.E.7 Roeding, Sebastian ························· 07.Mon.B.3 Sato, Takahiro ····························· 07.Mon.P1.51 Ponseca, Carlito S. ··························· 08.Tue.E.1 Roither, Stefan ······························· 08.Tue.P2.3 Sato, Takahiro ································ 08.Tue.P2.5 Pontecorvo, Emanuele ······················· 11.Fri.A.6 Roither, Stefan ····························· 08.Tue.P2.16 Sato, Takahiro ······························ 08.Tue.P2.19 Popmintchev, Dimitar ······················ 07.Mon.A.2 Roither, Stefan ································ 09.Wed.C.5 Sato, Takahiro ····························· 09.Wed.P3.17 Popmintchev, Dimitar ······················· 10.Thu.B.1 Roither, Stefan ································ 09.Wed.C.6 Sato, Takeshi ································ 07.Mon.P1.3 Popmintchev, Tenio ························· 07.Mon.A.2 Roland, Thomas ·························· 09.Wed.P3.26 Sato, Takeshi ································· 08.Tue.P2.1 Popmintchev, Tenio ····················· 07.Mon.P1.54 Ropers, Claus ·································· 08.Tue.B.4 Sawada, Ryohto ····························· 08.Tue.P2.1 Popmintchev, Tenio ·························· 10.Thu.B.1 Ropers, Claus ·································· 08.Tue.B.5 Sawai, Shota ································ 08.Tue.P2.55 Porras, Miguel A. ························· 07.Mon.P1.37 Ross, Matthew ································ 09.Wed.D.3 Saytashev, Ilyas ·························· 07.Mon.P1.59 Prasankumar, Rohit P. ····················· 07.Mon.D.3 Rossi, Giulio ································ 07.Mon.P1.55 Saytashev, Ilyas ······························· 10.Thu.C.2 Prémont-Schwarz, Mirabelle ······· 09.Wed.P3.16 Rossi, Giulio ································ 09.Wed.P3.37 Schafer, Kenneth J. ·························· 08.Tue.A.6 Prince, Kevin ································· 09.Wed.P3.5 Rossi, Giulio ································ 09.Wed.P3.60 Schäfer, Hanjo ································ 07.Mon.D.5 Prochnow, Oliver ························· 09.Wed.P3.53 Rössle, Matthias ·························· 08.Tue.P2.36 Schäfer, Hanjo ···························· 07.Mon.P1.41 Prokhorenko, Valentyn ················· 08.Tue.P2.22 Rothe, Neeke ······························ 09.Wed.P3.39 Schäffer, Martin ······························· 10.Thu.B.2 71 ▶ AUTHORS’ INDEX

Schalk, Oliver ·································· 07.Mon.B.5 Shinokita, Keisuke ······················· 08.Tue.P2.27 Sugimoto, Toshiki ····························· 08.Tue.E.5 Scherwitzl, Raoul ···························· 07.Mon.D.4 Shirai, Hideto ······························ 07.Mon.P1.43 Sugioka, Arata ································· 10.Thu.A.1 Scheu, Christina ·························· 09.Wed.P3.33 Shmidt, Bruno E. ····························· 07.Mon.B.2 Sugisaki, Mitsuru ························ 07.Mon.P1.12 Schick, Daniel ······························ 08.Tue.P2.36 Shmidt, Bruno E. ························· 09.Wed.P3.49 Sugisaki, Mitsuru ························ 09.Wed.P3.25 Schiffrin, Agustin ······························ 10.Thu.B.2 Siano, Marco ································ 09.Wed.P3.3 Suich, David ······························· 07.Mon.P1.22 Schiffrin, Agustin ······························ 10.Thu.B.6 Siemering, Robert ··························· 07.Mon.B.4 Sukegawa, Takashi ······················ 08.Tue.P2.51 Schimpf, Damian N. ························ 09.Wed.A.6 Sikorski, Marcin ······························ 07.Mon.D.6 Sundstrom, Villy ······························· 08.Tue.E.1 Schlawin, Frank ······························ 09.Wed.A.2 Simoes Brambila, Danilo ················ 08.Tue.P2.8 Suzuki, Takayuki ····························· 07.Mon.B.7 Schlotter, William F. ························· 07.Mon.D.4 Simpson, Robert ····························· 07.Mon.D.7 Suzuki, Takayuki ······························ 10.Thu.C.1 Schmeissner, Roman ······················ 09.Wed.A.6 Singh, Prashant C. ······················ 07.Mon.P1.27 Suzuki, Takeshi ······························· 07.Mon.C.3 Schmidt, Bruno E. ···························· 08.Tue.D.3 Singh, Rohan ·································· 07.Mon.C.3 Suzuki, Toshinori ····························· 07.Mon.B.7 Schmidt, Christian ·························· 09.Wed.B.1 Sistrunk, Emily F. ··························· 08.Tue.P2.6 Suzuki, Toshinori ····························· 07.Mon.E.4 Schmidt, Christian ··························· 10.Thu.A.5 Sistrunk, Emily F. ························ 09.Wed.P3.44 Suzuki, Toshinori ························· 07.Mon.P1.26 Schmidt, Slawa ································ 10.Thu.B.5 Skantzakis, Emmanouil ···················· 08.Tue.A.5 Suzuki, Toshinori ······························ 08.Tue.A.4 Schnitzenbaumer, Kyle ················ 07.Mon.P1.18 Skrobol, Christoph ·························· 09.Wed.B.3 Suzuki, Yoshi-Ichi ···························· 07.Mon.E.4 Schoenlein, Robert W. ····················· 09.Wed.D.2 Slaughter, Daniel S. ····················· 09.Wed.P3.14 Suzuki, Yoshi-Ichi ························ 07.Mon.P1.26 Schoenlein, Robert W. ····················· 09.Wed.D.3 Slenkamp, Karla ····························· 09.Wed.A.3 Suzuki, Yoshi-Ichi ····························· 08.Tue.A.4 Schöffl er, Markus ··························· 08.Tue.P2.3 Smith, Samuel L. ···························· 07.Mon.C.7 Swanwick, Michael ····················· 09.Wed.P3.37 Schöffl er, Markus ························· 08.Tue.P2.16 Soavi, Giancarlo ·························· 07.Mon.P1.33 Szlachetko, Jakub ··························· 09.Wed.D.1 Schöffl er, Markus ···························· 09.Wed.C.5 Soavi, Giancarlo ··························· 08.Tue.P2.34 Tachibana, Tetsuya ······················ 07.Mon.P1.46 Schöffl er, Markus ···························· 09.Wed.C.6 Soavi, Giancarlo ··························· 08.Tue.P2.45 Tachibana, Tetsuya ·························· 09.Wed.D.5 Scholes, Gregory D. ··························· 11.Fri.A.3 Sobolewski, Andrzej L. ················ 09.Wed.P3.20 Tachibana, Tetsuya ························ 09.Wed.P3.3 Schriber, Cinia ···························· 09.Wed.P3.59 Sobue, Kazuki ·································· 08.Tue.C.7 Tachibana, Tetsuya ························ 09.Wed.P3.5 Schroeter, Claus ······························ 09.Wed.C.3 Soifer, Hadas ······································ 11.Fri.B.1 Tahara, Tahei ·································· 07.Mon.E.1 Schröter, Marco ······························ 07.Mon.B.6 Soifer, Hadas ······································ 11.Fri.B.3 Tahara, Tahei ······························ 07.Mon.P1.27 Schubert, Martin ························· 07.Mon.P1.41 Soifer, Hadas ······································ 11.Fri.B.5 Tahara, Tahei ······························· 08.Tue.P2.15 Schubert, Olaf ·································· 10.Thu.A.3 Sola, Iñigo ···································· 08.Tue.P2.60 Tahara, Tahei ······························· 08.Tue.P2.26 Schuette, Bernd ···························· 09.Wed.P3.2 Solli, Daniel R. ·································· 08.Tue.B.5 Tahara, Tahei ·································· 10.Thu.D.5 Schulte, Jan ···································· 09.Wed.A.6 Somma, Carmine ························· 08.Tue.P2.46 Takahashi, Eiji J. ··························· 07.Mon.P1.6 Schulze, Jan ··································· 07.Mon.B.6 Son, Sang-Kil ································ 09.Wed.P3.3 Takahashi, Eiji J. ························· 07.Mon.P1.50 Schumann, Frank O. ··················· 07.Mon.P1.45 Sonoda, Kotaro ···························· 08.Tue.P2.19 Takahashi, Eiji J. ·························· 08.Tue.P2.18 Schumann, Frank O. ·························· 11.Fri.B.2 Sonoda, Kotaro ··························· 09.Wed.P3.17 Takahashi, Eiji J. ·························· 08.Tue.P2.49 Schuster, Conrad ························ 09.Wed.P3.39 Sotome, Masato ······························ 09.Wed.B.6 Takahashi, Eiji J. ··························· 09.Wed.P3.4 Schuurman, Michael ······················· 07.Mon.B.2 Southworth, Steven H. ···················· 09.Wed.D.1 Takahashi, Eiji J. ··························· 09.Wed.P3.7 Schwarz, Alexander ························· 10.Thu.C.6 Spaldin, Nicola ································ 07.Mon.D.1 Takaichi, Shinichi ························ 07.Mon.P1.12 Scopigno, Tullio ·································· 11.Fri.A.6 Springate, Emma ························ 07.Mon.P1.35 Takeda, Jun ································ 07.Mon.P1.29 Scotognella, Francesco ················ 08.Tue.P2.34 Springate, Emma ························· 08.Tue.P2.48 Takeda, Jun ································ 07.Mon.P1.42 Scotognella, Francesco ··············· 09.Wed.P3.33 Squibb, Richard ······························ 07.Mon.A.4 Takeda, Jun ································· 08.Tue.P2.38

INDEX Scotognella, Francesco ··············· 09.Wed.P3.42 Stagira, Salvatore ······················· 09.Wed.P3.42 Takeda, Jun ································ 09.Wed.P3.29 Sebesta, Aleksandar ··················· 09.Wed.P3.56 Stagira, Salvatore ······························ 11.Fri.B.1 Taketsugu, Tetsuya ····················· 07.Mon.P1.17 Sederberg, Shawn ··························· 10.Thu.C.6 Stagira, Salvatore ······························ 11.Fri.B.3 Taketsugu, Tetsuya ······················ 08.Tue.P2.14 Seki, Takashi ································ 08.Tue.P2.51 Starke, Ulrich ······························· 08.Tue.P2.48 Takeuchi, Eisuke ························· 07.Mon.P1.19 Sekikawa, Taro ··························· 07.Mon.P1.17 Staub, Urs ······································· 07.Mon.D.6 Takeuchi, Eisuke ························· 09.Wed.P3.19 Sekikawa, Taro ···························· 08.Tue.P2.14 Staudte, André ································ 09.Wed.C.6 Takeuchi, Satoshi ························· 08.Tue.P2.15 Seletskiy, Denis V. ··························· 09.Wed.B.1 Stein, Gregory J. ······························ 08.Tue.D.6 Takeuchi, Satoshi ························· 08.Tue.P2.26 Selig, Oleg ······································· 08.Tue.E.3 Steinbacher, Andreas ······················ 07.Mon.B.3 Takeuchi, Satoshi ···························· 10.Thu.D.5 Semonin, Octavi E. ··························· 08.Tue.E.2 Steinbacher, Andreas ···················· 07.Mon.P1.1 Takeya, Jun ····································· 08.Tue.E.5 Senftleben, Arne ····························· 09.Wed.C.3 Steinberg, Hadar ······························ 10.Thu.A.2 Tanaka, Hitoshi ··························· 07.Mon.P1.50 Senlik, Seckin ·································· 08.Tue.C.1 Steinmeyer, Gunter ·························· 10.Thu.C.5 Tanaka, Koichiro ····························· 09.Wed.B.5 Serbenta, Almis ································ 08.Tue.E.4 Stepanov, Andrey ····························· 08.Tue.E.1 Tanaka, Sei’ichi ·································· 11.Fri.A.7 Serrat, Carles ······························ 07.Mon.P1.49 Stolow, Albert ·································· 07.Mon.B.5 Tanaka, Shunsuke ···························· 08.Tue.E.5 Sfeir, Matthew ································· 08.Tue.E.2 Stolz, Wolfgang ······························· 07.Mon.C.2 Tanaka, Takashi ·························· 07.Mon.P1.50 Shaﬁ r, Dror ····································· 09.Wed.C.6 Strader, Mathew L. ·························· 09.Wed.D.2 Tassone, Francesco ···················· 09.Wed.P3.33 Sharma, Vandana ·························· 07.Mon.P1.9 Strader, Mathew L. ·························· 09.Wed.D.3 Tayama, Jumpei ································ 11.Fri.A.5 Shavorskiy, Andrey ······················ 09.Wed.P3.14 Strelow, Christian ····························· 08.Tue.E.2 Taylor, Antoinette J. ························· 07.Mon.D.3 Shaw, Justin M. ······························· 10.Thu.B.1 Strikwerda, Andrew C. ················· 08.Tue.P2.42 Tempea, Gabriel ··························· 08.Tue.P2.52 Shearer, Alex ······························· 07.Mon.P1.22 Strüber, Christian ····························· 10.Thu.B.3 Tempea, Gabriel ·························· 09.Wed.P3.51 Sheu, Yu-Miin ································· 07.Mon.D.3 Stuhldreier, Mayra C. ······················· 10.Thu.D.2 Temps, Friedrich ························· 07.Mon.P1.20 Sheves, Mordechai ······················ 08.Tue.P2.13 Subedi, Alaska ································ 07.Mon.D.1 Temps, Friedrich ························· 09.Wed.P3.20 Shigemasa, Eiji ······························ 08.Tue.P2.5 Suchowski, Haim ····························· 08.Tue.D.6 Temps, Friedrich ····························· 10.Thu.D.2 Shimakura, Noriyuki ···················· 07.Mon.P1.25 Suda, Akira ·································· 08.Tue.P2.11 Tenney, Ian ········································ 11.Fri.B.6 Shimamoto, Akihiro ····················· 07.Mon.P1.10 Suda, Akira ································· 09.Wed.P3.55 Terai, Hirotaka ································· 10.Thu.A.1 Shimano, Ryo ·································· 10.Thu.A.1 Sudmeyer, Thomas ····················· 09.Wed.P3.59 Thallmair, Sebastian ························ 10.Thu.D.3 Shin, Shik ··································· 07.Mon.P1.34 Suemoto, Tohru ··························· 07.Mon.P1.32 Thiel, Werner ······························· 08.Tue.P2.28 Shinohara, Yasushi ·························· 07.Mon.C.5 Suemoto, Tohru ···························· 08.Tue.P2.33 Thiré, Nicolas ·································· 07.Mon.B.2 72 AUTHORS’ INDEX ▶

Thiré, Nicolas ······························ 09.Wed.P3.49 Urbanek, Benedikt ··························· 10.Thu.A.3 Widdra, Wolf ······································ 11.Fri.B.2 Tielrooij, Klaas-Jan ························· 09.Wed.B.4 Uzawa, Yoshinori ······························ 10.Thu.A.1 Wieck, Andreas ······························· 07.Mon.C.3 Tisch, John W. G. ····························· 07.Mon.A.4 Valkunas, Leonas ····························· 08.Tue.C.1 Wiedbrauk, Sandra ························· 09.Wed.D.4 Tissot, Antoine ································ 09.Wed.E.6 van der Poll, Tom S. ························ 07.Mon.C.7 Wilcken, Roland ······························ 07.Mon.E.5 Titova, Lyubov ·································· 08.Tue.B.6 van der Veen, Monique ················· 08.Tue.P2.21 Wilcox, Daniel E. ······························ 08.Tue.C.1 Toda, Yasunori ·································· 08.Tue.D.5 van der Veen, Renske ······················ 09.Wed.E.6 Wilcox, Daniel E. ························· 09.Wed.P3.48 Togashi, Tadashi ····························· 07.Mon.B.7 Van Kuiken, Benjamin E. ················· 09.Wed.D.3 Wilk, Krystyna E. ······························ 08.Tue.C.4 Togashi, Tadashi ························· 07.Mon.P1.46 van Loosdrecht , Paul ······················· 08.Tue.E.4 Wilkins, Stuart B. ···························· 07.Mon.D.4 Togashi, Tadashi ························· 07.Mon.P1.50 van Wilderen, Luuk J. ······················ 09.Wed.A.5 Williams, Garth ······························· 09.Wed.E.1 Togashi, Tadashi ························· 07.Mon.P1.51 Varjú, Katalin ······························ 07.Mon.P1.60 Wimmer, Lara ·································· 08.Tue.B.5 Togashi, Tadashi ···························· 08.Tue.P2.4 Vazquez de Aldana, Javier R. ······· 07.Mon.P1.11 Wisnet, Andreas ·························· 09.Wed.P3.33 Togashi, Tadashi ···························· 08.Tue.P2.5 Velásquez-García, L. F. ················ 09.Wed.P3.37 Witting, Tobias ································ 07.Mon.A.4 Togashi, Tadashi ··························· 09.Wed.P3.5 Vicario, Carlo ·································· 09.Wed.B.2 Witting, Tobias ································· 08.Tue.D.7 Toida, Yuto ···································· 07.Mon.P1.5 Vicario, Carlo ······························ 09.Wed.P3.35 Wittmann, Emanuel ····················· 07.Mon.P1.56 Toida, Yuto ····································· 08.Tue.P2.4 Vidmar, Lev ································· 07.Mon.P1.33 Woerner, Michael ···························· 07.Mon.A.3 Tokura, Yoshinori ····························· 07.Mon.D.6 Viola, Daniele ······························· 08.Tue.P2.34 Woerner, Michael ························· 08.Tue.P2.46 Tollerud, Jonathan O. ·················· 09.Wed.P3.46 Vogelsang, Jan ································ 10.Thu.B.5 Woerner, Michael ····························· 10.Thu.A.4 Tolstikhin, Oleg I. ··························· 07.Mon.P1.9 Volz, Kerstin ···································· 07.Mon.C.2 Wolf, Jean-Pierre ····························· 08.Tue.E.1 Tolstikhin, Oleg I. ···························· 08.Tue.P2.9 von Reppert, Alexander ················ 08.Tue.P2.36 Wolf, Martin ································ 09.Wed.P3.53 Toma, Kazunori ································ 08.Tue.B.2 Voronin, Alexander ··························· 08.Tue.D.7 Wolf, Thomas ·································· 07.Mon.B.5 Toma, Kazunori ··························· 09.Wed.P3.54 Voronin, Alexander ······················· 08.Tue.P2.57 Wolf, Thomas ································· 08.Tue.P2.6 Tominaga, Junji ··························· 08.Tue.P2.43 Vozzi, Caterina ···························· 09.Wed.P3.42 Wolter, Benjamin ····························· 09.Wed.C.3 Tominaga, Junji ·························· 09.Wed.P3.34 Vozzi, Caterina ···························· 09.Wed.P3.49 Wolter, Steffen ································ 07.Mon.B.6 Tominaga, Keisuke ·························· 07.Mon.E.6 Vozzi, Caterina ··································· 11.Fri.B.1 Woo, Jae Heun ····························· 08.Tue.P2.29 Tominaga, Keisuke ······················ 07.Mon.P1.23 Vozzi, Caterina ··································· 11.Fri.B.3 Wu, Chenghao ···························· 09.Wed.P3.14 Tomizawa, Hiromitsu ··················· 07.Mon.P1.50 Vrakking, Marc J. J. ······················ 09.Wed.P3.2 Wu, Jeong Weon ·························· 08.Tue.P2.29 Tono, Kensuke ···························· 07.Mon.P1.51 Vu, Hoang L. ································· 07.Mon.P1.4 Wu, Kaung-Hsiung ······················· 08.Tue.P2.31 Tono, Kensuke ································ 09.Wed.D.5 Wachtveitl, Josef ························· 09.Wed.P3.27 Wu, Mengxi ······································ 08.Tue.A.6 Tono, Kensuke ······························ 09.Wed.P3.3 Wada, Shin-ichi ·························· 07.Mon.P1.46 Würthner, Frank ······························ 07.Mon.B.6 Tournois, Pierre ··························· 09.Wed.P3.58 Wada, Shin-ichi ······························ 09.Wed.D.5 Xi, Yu ··············································· 08.Tue.E.3 Trabattoni, Andrea ···························· 08.Tue.A.3 Wada, Shin-ichi ···························· 09.Wed.P3.3 Xian, Rui ······································ 08.Tue.P2.22 Trabattoni, Andrea ························ 08.Tue.P2.52 Wada, Shin-ichi ···························· 09.Wed.P3.5 Xiao, Dequan ······························ 09.Wed.P3.16 Trabattoni, Andrea ······················· 09.Wed.P3.51 Wadati, Hiroki ································· 07.Mon.D.6 Xiao, Yiming ································· 08.Tue.P2.29 Tremsin, Anton S. ························ 09.Wed.P3.14 Wagner, Martin ································ 10.Thu.C.3 Xie, Hongqiang ······························ 07.Mon.P1.2 Treps, Nicolas ································· 09.Wed.A.6 Wakabayashi, Naoki ··························· 11.Fri.A.5 Xie, Xinhua ····································· 08.Tue.P2.3 Trippel, Sebastian ······················· 09.Wed.P3.37 Walbran, Matthew ··························· 09.Wed.C.1 Xie, Xinhua ··································· 08.Tue.P2.16 INDEX Triscone, Jean-Marc ······················· 07.Mon.D.4 Walbran, Matthew ······················· 09.Wed.P3.45 Xie, Xinhua ······································ 09.Wed.C.5 Trojanowski, Peter ······················ 09.Wed.P3.27 Waldecker, Lutz ······························ 07.Mon.D.7 Xie, Xinhua ······································ 09.Wed.C.6 Troy, Tyler ··································· 09.Wed.P3.14 Wales, Benji ···································· 07.Mon.B.2 Xiia, Yuanqin ······························· 09.Wed.P3.10 Trugman, Stuart ······························ 07.Mon.D.3 Walker, Barry ·································· 07.Mon.A.2 Xiong, Gang ···································· 09.Wed.E.1 Trützschler, Andreas ···················· 07.Mon.P1.45 Wall, Simon ···································· 07.Mon.D.7 Xiong, Wei ··································· 07.Mon.P1.18 Trützschler, Andreas ··························· 11.Fri.B.2 Walls, Mike ································· 07.Mon.P1.54 Xiong, Wei ··································· 07.Mon.P1.54 Tseng, Chien-Ming ······················ 09.Wed.P3.23 Wang, Chuncheng ·························· 08.Tue.P2.9 Xiong, Wei ······································· 09.Wed.E.2 Tsuei, Ku-Ding ···························· 08.Tue.P2.31 Wang, Gouli ···································· 07.Mon.A.5 Xu, Bingwei ····································· 10.Thu.C.2 Tsui, Ying ········································· 08.Tue.B.6 Wang, Harn-Jiunn ························ 08.Tue.P2.31 Xu, Han ········································ 08.Tue.P2.17 Tsuji, Naoto ······································ 10.Thu.A.1 Wang, Yihua ····································· 10.Thu.A.2 Xu, Huailiang ································ 07.Mon.P1.2 Tudu, Barati ································ 09.Wed.P3.35 Wang, Yu-Ting ·································· 08.Tue.D.1 Xu, Huailiang ······························ 07.Mon.P1.10 Turchinovich, Dmitry ······················· 09.Wed.B.4 Wang, Zhen ····································· 10.Thu.A.1 Xu, Huailiang ·································· 09.Wed.C.5 Turcu, Edmond ···························· 07.Mon.P1.35 Wanie, Vincent ································ 07.Mon.B.2 Xu, Tian-Yu ·································· 08.Tue.P2.17 Turgut, Emrah ·································· 10.Thu.B.1 Ware, Matthew R. ························· 09.Wed.P3.8 Yabana, Kazuhiro ···························· 07.Mon.C.5 Turner, Joshua J. ····························· 07.Mon.D.2 Wark, Justin ···································· 09.Wed.E.1 Yabashi, Makina ······························ 07.Mon.B.7 Turner, Joshua J. ····························· 07.Mon.D.4 Watanabe, Hiroshi ······················· 07.Mon.P1.32 Yabashi, Makina ·························· 07.Mon.P1.46 Tzallas, Paraskevas ·························· 08.Tue.A.5 Watanabe, Hiroshi ························ 08.Tue.P2.33 Yabashi, Makina ·························· 07.Mon.P1.50 Ueda, Kiyoshi ································ 07.Mon.P1.9 Watanabe, Kazuya ··························· 08.Tue.E.5 Yabashi, Makina ·························· 07.Mon.P1.51 Ueda, Kiyoshi ······························ 07.Mon.P1.21 Watanabe, Shuntaro ···················· 07.Mon.P1.53 Yabashi, Makina ····························· 08.Tue.P2.4 Ueda, Kiyoshi ······························ 07.Mon.P1.46 Watanabe, Shuntaro ····················· 08.Tue.P2.51 Yabashi, Makina ····························· 08.Tue.P2.5 Ueda, Kiyoshi ································· 08.Tue.P2.9 Watanabe, Takahiro ····················· 07.Mon.P1.50 Yabashi, Makina ······························ 09.Wed.D.5 Ueda, Kiyoshi ·································· 09.Wed.D.5 Wei, Fei ··········································· 07.Mon.A.5 Yabashi, Makina ···························· 09.Wed.P3.3 Ueda, Kiyoshi ································ 09.Wed.P3.3 Weigel, Alexander ······················· 09.Wed.P3.56 Yabashi, Makina ···························· 09.Wed.P3.5 Ueda, Kiyoshi ································ 09.Wed.P3.5 Weinberg, David J. ······················ 07.Mon.P1.24 Yabushita, Atsushi ···························· 08.Tue.D.1 Uemura, Takafumi ···························· 08.Tue.E.5 Weiss, Emily ······························· 07.Mon.P1.24 Yabushita, Atsushi ···························· 08.Tue.D.2 Ullrich, Joachim ······························ 09.Wed.C.3 Weisshaupt, Jannick ······················· 07.Mon.A.3 Yada, Hiroyuki ································· 09.Wed.B.6 Umakoshi, Takayuki ····················· 08.Tue.P2.47 Whaley-Mayda, Lukas ·················· 08.Tue.P2.24 Yakovlev, Vladislav S. ······················· 10.Thu.B.6 Unterreiner, Andreas-Neil ················ 07.Mon.B.5 Whaley-Mayda, Lukas ················· 09.Wed.P3.24 Yakushi, Kyuya ···························· 07.Mon.P1.40 Uozumi, Shin-ichi ························ 07.Mon.P1.44 Widdra, Wolf ······························· 07.Mon.P1.45 Yakushi, Kyuya ···························· 09.Wed.P3.40 73 ▶ AUTHORS’ INDEX

Yakushi, Kyuya ···························· 09.Wed.P3.41 Yamazaki, Takao ························· 09.Wed.P3.21 Zauleck, Julius ································ 10.Thu.D.3 Yalunin, Sergey ································ 08.Tue.B.5 Yamochi, Hideki ·························· 09.Wed.P3.36 Zegkinoglou, Ioannis ··················· 09.Wed.P3.14 Yamada, Kentaro ·························· 08.Tue.P2.41 Yan, Li ············································· 07.Mon.D.3 Zeng, Bin ······································ 07.Mon.P1.2 Yamada, Yuki ·································· 09.Wed.E.3 Yanagi, Kazuhiro ························· 07.Mon.P1.42 Zewail, Ahmed ································ 09.Wed.E.6 Yamaguchi, Keita ························· 08.Tue.P2.33 Yang, Chunfan ································· 07.Mon.C.6 Zhang, Haisu ································· 07.Mon.P1.2 Yamaguchi, Shoichi ····················· 07.Mon.P1.27 Yang, Chunfan ····························· 09.Wed.P3.28 Zhang, Hui ·································· 09.Wed.P3.33 Yamaguchi, Tomohiko ················· 09.Wed.P3.55 Yang, Yujia ······································· 08.Tue.B.3 Zhang, Li ········································ 09.Wed.C.6 Yamakawa, Hiromichi ······················ 09.Wed.B.6 Yang, Zhao ·································· 09.Wed.P3.10 Zhang, Qingbing ··························· 07.Mon.P1.7 Yamakawa, Koichi ······················· 07.Mon.P1.50 Yano, Koki ··································· 09.Wed.P3.25 Zhang, Sheng ····························· 09.Wed.P3.10 Yamamoto, Kaoru ························ 07.Mon.P1.40 Yanover, Diana ································ 07.Mon.C.6 Zhang, Xiaoshi ···························· 07.Mon.P1.54 Yamamoto, Kaoru ························ 09.Wed.P3.40 Yao, Jinping ·································· 07.Mon.P1.2 Zhang, Xin ·································· 09.Wed.P3.43 Yamamoto, Kaoru ························ 09.Wed.P3.41 Yao, Makoto ································ 07.Mon.P1.46 Zhang, Yizhu ··································· 09.Wed.D.5 Yamamoto, Shuhei ······················ 07.Mon.P1.44 Yao, Makoto ···································· 09.Wed.D.5 Zhang, Yu ···································· 09.Wed.P3.22 Yamamoto, Takafumi ······················· 09.Wed.B.5 Yao, Makoto ·································· 09.Wed.P3.3 Zhang, Zhonghua ························ 09.Wed.P3.10 Yamamoto, Yo-Ichi ·························· 07.Mon.E.4 Yao, Makoto ·································· 09.Wed.P3.5 Zhao, Jiayu ··································· 09.Wed.P3.1 Yamanaka, Yusuke ··························· 10.Thu.C.4 Yartsev, Arkady ································ 08.Tue.E.1 Zheltikov, Alexei ······························· 08.Tue.D.7 Yamane, Keisaku ····························· 08.Tue.D.5 Yase, Satoshi ······························ 07.Mon.P1.46 Zheltikov, Alexei ····························· 08.Tue.P2.7 Yamanouchi, Kaoru ······················· 07.Mon.P1.2 Yase, Satoshi ································ 09.Wed.P3.5 Zheltikov, Alexei ··························· 08.Tue.P2.57 Yamanouchi, Kaoru ······················· 07.Mon.P1.6 Ye, Hong ····································· 09.Wed.P3.37 Zheng, Kaibo ···································· 08.Tue.E.1 Yamanouchi, Kaoru ······················· 07.Mon.P1.8 Ye, Hong ····································· 09.Wed.P3.60 Zheng, Yi Ying ····························· 09.Wed.P3.15 Yamanouchi, Kaoru ····················· 07.Mon.P1.10 Yeh, Tien-Tien ····························· 07.Mon.P1.43 Zhou, Binbin ································ 08.Tue.P2.59 Yamanouchi, Kaoru ····················· 07.Mon.P1.16 Yeh, Tien-Tien ······························ 08.Tue.P2.31 Zhou, Chun ·································· 08.Tue.P2.51 Yamanouchi, Kaoru ····················· 07.Mon.P1.50 Yokoyama, Atsushi ························ 09.Wed.P3.9 Zhou, Yueming ······························ 07.Mon.P1.7 Yamanouchi, Kaoru ························ 08.Tue.P2.2 Yoneda, Yusuke ··························· 07.Mon.P1.19 Zhou, Yueming ································ 09.Wed.C.6 Yamanouchi, Kaoru ························ 08.Tue.P2.3 Yoneda, Yusuke ································ 08.Tue.C.6 Zhu, Diling ······································ 07.Mon.D.6 Yamanouchi, Kaoru ······················ 08.Tue.P2.16 Yonemitsu, Kenji ························· 07.Mon.P1.40 Zhu, Diling ······································ 09.Wed.E.1 Yamanouchi, Kaoru ······················ 08.Tue.P2.19 Yonemitsu, Kenji ························· 09.Wed.P3.40 Ziaja, Beata ··································· 09.Wed.P3.3 Yamanouchi, Kaoru ······················ 08.Tue.P2.25 Yonezawa, Kento ····························· 10.Thu.D.5 Ziessel, Raymond ························ 09.Wed.P3.26 Yamanouchi, Kaoru ························· 09.Wed.C.2 Yoshino, Shngo ······························· 07.Mon.C.4 Zigler, David ···································· 09.Wed.E.5 Yamanouchi, Kaoru ························· 09.Wed.C.5 Yoshizawa, Masayuki ······················· 08.Tue.C.7 Zigmantas, Donatas ··························· 11.Fri.A.4 Yamanouchi, Kaoru ······················· 09.Wed.P3.4 Young, Ben-Li ······························ 08.Tue.P2.31 Zinth, Wolfgang ······························· 09.Wed.D.4 Yamanouchi, Kaoru ······················· 09.Wed.P3.7 Yun, Won Seok ····························· 08.Tue.P2.39 Zinth, Wolfgang ··························· 09.Wed.P3.11 Yamanouchi, Kaoru ····················· 09.Wed.P3.17 Zair, Amelle ····································· 07.Mon.A.4 Zinth, Wolfgang ······························· 10.Thu.D.4 Yamanouchi, Kaoru ····················· 09.Wed.P3.21 Zalkovskij, Maksim ······················ 08.Tue.P2.42 Zubko, Pavlo ··································· 07.Mon.D.4 Yamazaki, Kaoru ························· 07.Mon.P1.21 Zamponi, Flavio ······························· 10.Thu.A.4 Zusin, Dmitriy ·································· 10.Thu.B.1 INDEX