Appendix 2 – page 1

INTERNATIONAL UNION OF RADIO SCIENCE

1. NAME OF CANDIDATE: ...... Last, First, Middle

PRESENT OCCUPATION: ...... Position, Organization ......

BUSINESS ADDRESS: ......

HOME ADDRESS: ......

BIRTHDATE ...... NATIONALITY: ...... SEX: male - female (Underline the appropriate)

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year ......

3. PROPOSED CITATION (not more than thirty words) ......

4. NOMINATOR: ...... ADDRESS: ...... PHONE: ...... FAX: ...... E-MAIL : ......

Appendix 2 – page 2 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

From (year) to (year) Name of Company/Institution Position and Responsibilities

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Appendix 2 – page 3 6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

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7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex – maximum 5 pages)

- Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions.

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT

Balthasar van der Pol Gold Medal

John Howard Dellinger Gold Medal

Appleton Prize

Booker Gold Medal

Issac Koga Gold Medal

Appendix 2 – page 4 9. ARGUMENTS IN SUPPORT OF THE NOMINATION (Limit to this page)

...... Nader Engheta

Attachment to the URSI Nomination Form

Question 5: Professional History

July 1987 Department of Electrical Engineering (Dept. of Electrical and Systems to present Engineering since February 15, 2002) University of Pennsylvania, Philadelphia, PA H. Nedwill Ramsey Professor (January 1, 2005-present) Professor of EE (July 1995-present) Professor of Bioengineering (Secondary appointment) (5/2005-present) UPS Foundation Distinguished Educator chair holder (7/1999-6/2000) Associate Professor of EE (tenured) (July 1990-June 95) Assistant Professor of EE (July 1987-June 1990) EE Graduate Group Chairman (July 1993-June 1997) Member of Applied Mathematics and Computational Science Graduate Group (Sept. 2008- present) Member of Bioengineering Graduate Group (Sept. 96- present) Member of the Mahoney Institute of Neurological Sciences, U. of PA (February 1995-present) Affiliated with the Center for Science and Engineering of Nanoscale Systems (SENS), Nano-Bio Interface Center, UPenn (Jan. 2004- present) Affiliated with the Center for Sensor Technologies, UPenn (June 2000 – present)

March-May 1998 Visiting Professor under Fulbright Naples Chair Award (sabbatical) Universita' di Napoli Dipartimento di Ingegneria Elettronica Napoli, Italia

June 1983 Senior Research Scientist to June 1987 Kaman Sciences Corporation, Dikewood Division Santa Monica, California.

June 1983 Visiting Research Associate in Electrical Engineering (Part Time) to June 1987 Caltech, Pasadena, California

Spring 1986 Visiting Lecturer in Electrical Engineering (Part Time) UCLA

June 1982 Postdoctoral Research Fellow in Electrical Engineering to June 1983 Caltech, Pasadena, California

January 1979 Graduate Research Assistant in Electrical Engineering to June 1982 Caltech, Pasadena, California

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Question 6: Honours, Awards, Professional Society Membership, Major Professional Government or International Committee Membership

• Fellow of the American Association for the Advancement of Science (AAAS) (2010) • Fellow of the American Physical Society (APS) (2008) • Fellow of the Optical Society of America (OSA) (1999) • Fellow of IEEE (1996) • Recipient of the 2008 George H. Heilmeier Award for Excellence in Research, School of Engineering and Applied Science, University of Pennsylvania, December 2007. • Selected as one of the Scientific American Magazine 50 Leaders in Science and Technology in 2006, for his contributions to the field of plasmonics, November 2006. • Holder of the endowed H. Nedwill Ramsey Chaired Professorship in Electrical and Systems Engineering (Jan 1, 2005 - present) • Recipient of the IEEE Third Millennium Medal, April 2000. • Recipient of a Guggenheim Fellowship Award, 1999. • Holder of the UPS Foundation Distinguished Educator term Chair for one-year term (Academic) Year 1999-2000) • Recipient of the Fulbright Chair Award for Naples, Italy through the Fulbright Distinguished Chairs program (1998). (First recipient of Naples Chair in the field of engineering). • Recipient of a NSF Presidential Young Investigator (PYI) Award (1989). • Recipient of the W. M. Keck Foundation's 1995 Engineering Teaching Excellence Award, 1995. • Recipient of the Christian F. and Mary R. Lindback Foundation Award for distinguished teaching, April 1994. • Recipient (two times) of the S. Reid Warren, Jr. Award for distinguished teaching, School of Engineering and Applied Science, University of Pennsylvania, October 1993, and April 2002. • Recipient of the 2008 Computer Simulation Technology (CST) University Publication Award for the paper A. Alu and N. Engheta, “Cloaking and Transparency for Collections of Particles with Metamaterial and Plasmonic Covers,” Optics Express, Vol. 15, No. 12, pp. 7578-7590, June 11, 2007. • Recipient of Magistri Artivm honoris causa (Honorary MA degree) from University of Pennsylvania, 1990 • (Courtesy) Adjunct Professor of the Electromagnetics Academy at Zheijiang University, Hangzhou, China, November 2004-November 2006 • Elected as the Vice-Chair (for 2010) and Chair (for 2012) for the Gordon Research Conference on Plasmonics. • Member of the External Advisory Board for the Sandia National Laboratory’s Metamaterials Grand Challenge Program, October 2008 – Present. • Chair of the External Advisory Board for the University of Southampton’s EPSRC Programme on Nanostructured Photonic Metamaterials, January 2010- Present. • Member of the DARPA’s Defense Sciences Research Council (DSRC), September 1, 2006 – Present. • Our paper “Cloaking a Sensor” published in Phys. Rev. Letters on June 8, 2009 was selected to be highlighted as an Editors’ Suggestion, and also for highlighting in the online APS publication Physics. • Plenary Speaker on the topic of “Linear and Nonlinear Elements in Metactronics” in Opening Ceremony of the NATO Advanced Research Wokrshop META’10, 2nd International Conference on Metamaterials, Photonic Crystals, and Plasmonics, Cairo, Egypt, February 22-25, 2010. • Plenary Speaker on the topic of “Seeing the Unseen: How Can we Learn from Polarization- Sensitive Eyes and How Can We Design Better Imaging Systems?” in Opening Ceremony of the

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2009 European Microwave Conference (EuMC) as Part of the 2009 European Microwave Week (EuMW), Rome, Italy, September 28-October 2, 2009.. • Invited speaker at the Booz-Allen-Hamilton Distinguished Colloquium Series at Department of Electrical and Computer Engineering, University of Maryland at College Park, College Park, Maryland, September 11, 2009, with a talk entitled “Taming the Light at the Nanoscale”. • Plenary Speaker on the topic of “Taming the Light with Metamaterials” in the NanoScience and Engineering Part of the 2009 SPIE-The International Society for Optical Engineering on Optics and Photonics, San Diego, California, August 2-6, 2009. • Plenary Speaker on the topic of “What to Do with Extreme Metamaterials” at the 2009 ETOPIM’8 Conference, Crete, Greece June 11, 2009. • Plenary Speaker on the topic of “Circuits with Light at the Nanoscale: A New Paradigm for Nanoscale Information Processing” at the 43th Annual Conference on Information Sciences and Systems (CISS 2009), Baltimore, MD, March 18, 2009. • Plenary Speaker on the topic of “Circuits with Light at the Nanoscale” at the 13th Interantional Symposium on Antenna Technology and Applied Electromagnetics/Canadian Radio Sciences Meeting/ANTEM/URSI/CNC, Banff, AB, Canada, February 18, 2009. • Invited speaker at the Distinguished Lecturer Series at Department of Electrical and Computer Engineering, Rice University, Houston, TX, February 12, 2009, with a talk entitled “Circuits with Light at the Nanoscale”. • Plenary Speaker on the topic of “Circuits with Light at the Nanoscale” at The 6th International System-on-Chip Conference, Exhibit and Workshop, Newport Beach, California, November 5, 2008. • Keynote speech on the topic of “Extreme-Parameter Metamaterials,” at the Metamaterials’ 2008: 2nd International Congress on Advanced Electromagnetic Materials in Microwave and Optics, Pamplona, Spain, September 21-26, 2008. • Delivered the single Public Lecture (a large Plenary speech) on the topic of “Seeing the Unseen: From Polarization-Sensitive Eyes to Biologically-Inspired Sensing and Imaging Science” at the 2008 XXIX General Assembly of the International Union of Radio Science (URSI-GA 2008), Chicago, Illinois, August 7-16, 2008. • Keynote speech on the topic of “Metactronics: Optical Circuits and Information Processing in Nanoworlds” at the NATO Advanced Research Workshop on Metamaterials for Secure Information and Communication Technologies (META’08), Marrakech, Morocco, May 7-10, 2008. • Invited speaker at the Lester Eastman Seminar Series at School of Electrical and Computer Engineering, Cornell University, Ithaca, NY, November 30, 2007, with a talk entitled “Nanocircuits with Light and Wireless at Nanoworlds”. • Invited talk at the “Frontiers in Physics” at the 2007 Industrial Physics Forum, the talk entitled “Circuits with Light at the Nanoscale,” in Seattle, WA, October 16, 2007. • Invited member of a panel on “Metamaterials: Invisible Revolution,” at theEMTech: Emerging Technology Conference @ MIT, Cambridge, MA, September 25-27, 2007. • Keynote Speech at the Plasmoic Metamaterials Conference of the 2007 SPIE-The International Society for Optical Engineering on Optics and Photonics, the talk entitled “Plasmonic Metamaterials: The Tale of Two Phenomena,” in San Diego, California, August 26-30, 2007. • Plenary Speaker at the Optical Society of America (OSA) Topical Meeting on Nanophotonics, talk entitled “What do Optical Nanocircuits, Squeezing Light, and Supermicroscopy Have in Common?” in Hangzhou, China, June 18-22, 2007. • Plenary Speaker at the 51st International Conference on Electron, Ion, Photon Beam Technology and Nanotechnology (EIPBN) talk on the topic of “Metamaterial and Plasmonic Nanocircuits: Towards a New Paradigm in Optica Nanoelectronics” in Denver, CO, May 29-June 1, 2007. • Kilby Keynote Speaker on the topic of “Seeing the Invisible: Polarization Vision in Nature and Non-Invasive Imaging and Sensing Applications” at the 2006 Government Microcircuit

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Applications and Critical Technology Conference (GOMACTech 2006), San Diego, CA, March 20-23, 2006. • Delivered one of the three General Lectures (large plenary speech) on the topic of “Metamaterials and Plasmonic Phenomena” at the XXVIII General Assembly of International Union of Radio Science (URSI), in New Delhi, India, October 23-29, 2005. • Keynote Speaker at the International Workshop on Antenna Technology: Small Antennas and Novel Metamaterials (iWAT’05), talk on the topic of “Nanocircuit Elements, Nano-Transmiss ion Lines, and Nano-Antennas Using Plasmonic Materials in the Optical Domains,” in Singapore, March 7-9, 2005. • Panelist on the session “RF/Microwave/Millimeter-Wave Applications Using Left-Handed Metamaterials,” at the 2005 IEEE Microwave Theory ad Techniques International Microwave Symposium (IMS’05), Long Beach, CA, June 12-17, 2005. • Plenary Speaker at the International Union of Radio Science (URSI)-U.S. National Committee (USNC), National Radio Science Meeting talk on the topic of “Seeing the Invisible: Polarization Vision, Its Biophysical Mechanism and Non-Invasive Imaging Applicastions” in Boulder, CO, January 5-8, 2005. • Invited Keynote Speaker on "Metamaterials and Plasmonic Media: Theory and Potential Applications," at Bianisotropics’04: 10th International Conference on Complex Media and Metamaterials” in Ghent, Belgium, September 22-24, 2004. • Distinguished Lectures Series Speaker at Temple University, College of Engineering, November 13, 2006, on “Metamaterials, Shrinking Circuit Elements, and Nanooptics.” • Distinguished Lectures Series Speaker at Ohio State University, Department of Electrical and Computer Engineering, Febuary 9, 2006, on “Metamaterials, Shrinking Circuit Elements, and Nanooptics.” • Distinguished Lectures Series Speaker at University of Toronto, Edward S, Rogers Sr. Department of Electrical and Computer Engineering, January 18, 2005, on “Metamaterials, Shrinking Components, and Near-Field Nano-Devices and Systems.” • Distinguished Seminar Speaker at University of Arizona, Department of Electrical and Computer Engineering, April 20, 2004, on “Metamaterials and Plasmonic Nanostructures: Concepts, Salient Features, and Potential Applications.” • Invited Plenary Speaker on "Electromagnetics of Complex Media and Metamaterials," in a plenary session of the Mathematical Methods in Electromagnetic Theory (MMET*2002) conference, in Kiev, Ukraine, Sept. 10-13, 2002. • Invited Plenary Speaker on "Fractionalization Methods and Their Applications in Radiation and Scattering Problems," in a plenary session of the Mathematical Methods in Electromagnetic Theory (MMET*2000) conference, in Kharkov, Ukraine, Sept. 12-15, 2000. • Invited Keynote Speaker on "Fractional Derivatives, Fractional Integrals and Electromagnetic Theory," in the plenary session of the International Conference on Computational Electromagnetics and Its Applications (ICCEA'99), in Beijing, China, Nov. 1-4, 1999. • Invited Plenary Speaker on "Fractional Calculus and Fractional Paradigm in Electromagnetic Theory," in a plenary session of the Mathematical Methods in Electromagnetic Theory (MMET*98) conference, in Kharkov, Ukraine, June 2-5, 1998. • Invited Plenary Speaker on "Biologically Inspired Polarization-Difference Imaging," in a plenary session of the 27th European Microwave Conference (EuMC'97) in Jerusalem, Israel, September 8-11, 1997. • Invited Plenary Speaker on Chiral and Complex Material in the 14th Triennial URSI International Symposium on Electromagnetic Theory, Sydney, Australia, on August 17-20, 1992. • IEEE Antennas and Propagation Society (AP-S) Distinguished Lecturer for June 1997-December 1999. • Member of the Scientific Advisory Board of the Ph.D. Program in Applied Electromagnetics in Universities of Salerno and Benevento, Italy (January 1999)

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• Former Associate Editor of IEEE Antennas and Propagation Letters (AWPL) (Jan. 2002– December 2007) • Former Associate Editor of IEEE Transactions on Antennas and Propagation (Oct. 1996– July 2001) • Former Associate Editor of Radio Science (Nov.1991-Dec. 1996) • Member of the Editorial Board of the Istituto Superiore Mario Boella Book Series in Radio Science, SciTech Publishing, October 2009- present. • Member of the Editorial Board of the Journal Waves in Random and Complex Media (WRCM), Taylor and Francis Pub., October 2008- present. • Member of the Editorial Board of the newly founded journal Metamaterials, sponsored by the European Metamorphose Network of Excellence, Elsevier Pub., April 2006- present. • Co-Guest Editor (with G. Eleftheriades (U. Toronto) the IEEE Proceedings, special issue on “Metamaterials: Fundamentals and Applications in the Microwave and Optical Regimes”, in progress, to appear in Spring 2011. • Co-Guest Editor (with V. Shalaev (Purdue U.), N. Litchinitser (SUNY, Buffalo), R. McPhedran (U. Sydney), E. S hamonina ( University of Erlangen-Nuremberg), and T. Klar (Technische Univerität Ilmenau), Special issue of the IEEE Journal of Selected Topics in Quantum Electronics on the topic of “Metamaterials”, Vol. 16, No. 2, pp. 363-458, March-April 2010. • Co-Guest Editor (with Gennady Shvets (UT Austin) of the special issue of the Solid States Communications on "Negative refraction and metamaterials for optical science and engineering", expected to appear September 2007. • Co-Guest Editor (with R. W. Ziolkowski) of the special issue of the IEEE Transactions on Antennas and Propagation on "Metamaterials", Oct. 2003. • Co-Guest Editor (with L. B. Felsen) of the special issue of the journal Wave Motion on "Electrodynamics in Complex Environments," September 2001.) • Guest Editor of the Part Special issue of the Journal of the Franklin Institute on Antennas and Microwaves for "the 13th Annual Benjamin Franklin Symposium" held on May 5, 1995 in Philadelphia, PA. This special issue contains some selected papers from this symposium, vol. 332B, No. 5, 1995. • Guest Editor of the special issue of the Journal of Electromagnetic Waves and Applications (JEWA) on "Wave Interaction with Chiral and Complex Media," Vol. 6, No. 5/6, May-June 1992. • Member of the International Editorial Board of the Journal of Electromagnetic Waves and Applications (1993-2001). • Recipient of the 1991 Outstanding Chapter Award in the IEEE Philadelphia Section for Cha ir ing the Antennas and Propagation/Microwave Theory and Technique Joint Chapter of the Philadelphia Section, February 29, 1992. • Selected as one of the Distinguished Graduates of the University of Tehran’s School of Engineering on the occasion of the 70th Anniversary of School of Engineering of University of Tehran, December 2004. • Listed in Who's Who in Science and Engineering. • Listed in American Men & Women of Science • Listed in Who's Who in Technology. • Listed in Who's Who in The East. • Listed in Who's Who in The World. • Listed in Who's Who in America.

Scientific and Professional Societies:

Fellow : Institute of Electrical and Electronics Engineers (IEEE),

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elected as a Fellow (1996) for “contributions to the electromagnetic theory of complex media”.

Member of the following IEEE societies: Antennas and Propagation Microwave Theory and Techniques Lasers and Electro-Optics Geoscience and Remote Sensing Electromagnetic Compatibility

Fellow : Optical Society of America (OSA), elected as a Fellow (March 1999) for “contributions to electromagnetic theory and imaging science.”

Fellow : American Physical Society (APS), elected as a Fellow (November 2008) “For development of concepts of metamaterial-inspired optical lumped nanocircuits, and for ground breaking contributions to the fields of metamaterials, plasmonic nano-opt ics, biologically-inspired imaging, and electrodynamics.”

Fellow : American Association for the Advancement of Science (AAAS), elected as a Fellow (December 2009) “For outstanding contributions to thefields of metamaterials, plasmonic nano-opt ics, biologically-inspired imaging, and electrodynamics, and for developing the concepts of metactronics and metamaterial-inspired lumped nanocircuits.”

Member: U.S. National Committee (USNC) of International Union of Radio Science (URSI) Commission D on (Electronics and Photonics), Commission B (Fields and Waves). And Commission K (Electromagnetics in Biology and Medicine) Member-at-Large of USNC-URSI from January 1, 2005 till December 31, 2007 Vice-Chair/Chair-Elect of URSI-USNC Commission B, January 2006-December 2008 Chair of URSI-USNC Commission B, January 2009-December 2011 American Association for the Advancement of Science (AAAS) Material Research Society (MRS) Sigma Xi Society of Photo-Optical Instrumentation and Engineering (SPIE) Institute of Physics (IOP), United Kingdom Electromagnetics Academy

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Question 7: Principal Publications and Patents

Nominee’s Ten Most Significant Publications

• N. Engheta, “Circuits with Light at Nanoscales: Optical Nanocircuits Inspired by Metamaterials”, Science, Vol. 317, pp. 1698-1702, September 21, 2007.

(Several news briefs about this work were written in various news websites, e.g., EE Times, a cover-page story article entitled “Professor posits metananocircuits as electronics’ next frontier’” by Sunny Bains February 27, 2008 (in March 3, 2008 issue) http://www.eetimes.com/showArticle.jhtml;?articleID=206900564; Laser Focus World, a news feature entitled “Photonic Frontier: Integrated Optics: Metananocircuits can operate at optical frequencies,” by Jeff Hecht, Volume 43, Issue 12, December 1, 2007, ); Nanotechweb.org, from UK Institute of Physics Publishing, a news feature entitled “Simulation shine a light on optical wire: Nanowaveguide models offer clues to wiring up optical nanocircuits,” by James Tyrrell, Posted on November 19, 2007, http://nanotechweb.org/cws/article/tech/31824 ); Photonics Spectra, a news feature entitled “Review Provides Blueprint for Optical Nanocircuits,” by David Shenkenberg in the section on Presstime Bulletin, October 2007, p. 18. http://www.photonics.com/content/spectra/2007/October/news/89213.aspx ); Nanowerk, a news feature entitled “Metamctronics: A Metamaterial-Based Nanotechnology Approach towards Electronics” by Michael Berger, Posted on October 16, 2007, http://www.nanowerk.com/spotlight/spotid=2947.php )

• A. Alu and N. Engheta, “Tuning the Scattering Response of Optical Nanoantennas with Nanocircuit Loads”, in Nature Photonics, Vol. 2, pp. 307-310, May 2008.

(This paper was highlighted in the Nature Photonics in the News and Views article entitled “Engineering optical nanoantennas” by Mark Brongersma in May 2008 and in Optics and Photonics Focus (online) entitled “Twisting the Knob of Light” by Giorgio Volpe, in Volume 4, Story 3 of Optics and Photonics Focus, February 9, 2009)

• N. Engheta, “An Idea for Thin, Subwavelength Cavity Resonators Using Metamaterials with Negative Permittivity and Permeability,” IEEE Antennas and Wireless Propagation Letters. Vol. 1, pp. 10-13, 2002.

• A. Alu and N. Engheta, “Achieving Transparency with Metamaterial and Plasmonic Coatings, ” Physical Review E, vol. 72, 016623, 2005.

(Numerous (more than hundreds) news briefs about this work were written in various international news papers and news web sites, e.g., an article by Philip Ball, entitled "Engineers devise invisibility shield” in Nature News, February 2005 http://www.nature.com/news/2005/050228/full/050228-1.html)

• N. Engheta, A. Salandrino, A. Alu, “Circuit Elements at Optical Frequencies: Nano- Inductor, Nano-Capacitor, and Nano-Resistor,” Physical Review Letters, Vol. 95, 095504, August 26, 2005.

(Several news briefs about this work were written in various news websites, e.g. a news brief by Phil Schewe and Ben Stein, “ Circuit elements for optical frequencies” in Physics News Update, Bulletin of Physics News of American Institute of Physics (AIP) http://www.aip.org/pnu/2005/split/737-1.ht ml; Optics and Photonics News (OPN), monthly magazine of Optical Society of America. Article by Patricia Daukantas, Senior Writer/Editor, entitled “Lumped Circuit Elements for Optical Frequencies,” Vol. 17, No. 6, p. 9, 2006, http://www.osa- opn.org/abstract.cfm?URI=OPN-17-6-8)

• A. Alu and N. Engheta, “Cloaking a Sensor, ” in Physical Review Letters, 102, 233901, June 8, 2009.

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(A news brief in Science News article entitled “Cloaked Eye Still Sees” by Laura Sanders, April 15, 2009, http://www.sciencenews.org/view/generic/id/42803/description/Cloaked_eye_still_sees about our Physical Review Letters article on “Cloaking a Sensor”, Physical Review Letters, 2009. Also APS Publication Physics highlight article entitled “Seeing without being seen” by Javier Garcia di Abajo, Physics Vol. 2, 47, 2009. http://physics.aps.org/viewpoint-for/10.1103/PhysRevLett.102.233901 about our Physical Review Letters article on “Cloaking a Sensor”, Physical Review Letters.)

• A. Alu and N. Engheta, “All-Optical Metamaterial Circuit Board at the Nanoscale,” Physical Review Letters, Vol. 103, 143902, September 29, 2009.

(A news brief in PhysOrg.com article entitled “Running Electronics Using Light” by Miranda Marquit, PhysOrg.com October 19, 2009. http://www.physorg.com/news175161170.html about our Physical Review Letters article on “All- Optical Metamaterial Circuit Board at the Nanoscale”, Physical Review Letters,. Vol. 103, 143902, October 2, 2009.)

• M. G. Silveirinha and N. Engheta, “Tunneling of Electromagnetic Energy through Sub- Wavelength C hannels and Bends Using Epsilon-Near-Zero (ENZ) Materials,” in Physical Review Letters, Vol. 97, 157403, October 2006.

• M. G. Silveirinha and N. Engheta, “Transporting an Image through a Subwavelength Hole,” Physical Review Letters, Vol. 102, 103902, March 13, 2009.

(A research highlight article in Nature Photonics, entitled “In a Squeeze” written by the editors in page 243, Vol. 3, May 2009 issue of Nature Photonics, www.nature.com/naturephotonics about this Physical Review Letters article on “Transporting an Image through Subwavelength hole”, Physical Review Letters, Vol. 102, 103902, March 13, 2009.)

• M. P. Rowe, E. N. Pugh, Jr., J. S. Tyo, and N. Engheta, "Polarization-Difference Imaging: A Biologically Inspired Technique for Observation through Scattering Media," Optics Letters, Vol. 20, No. 6, pp. 608-610, March 15, 1995.

(News briefs were written about this work, e.g., London Times article by Nigel Hawkes on "As clear as mud to a fish" June 3, 1996, p. 16)

SAMPLE OF PUBLICATIONS (FROM A LIST OF NUMEROUS PUBLICATIONS) Book (edited)

N. Engheta and R. W. Ziolkowski, (editors), Metamaterials: Physics and Engineering Explorations, Wiley-IEEE Press, 414 pages, June 2006. Special Issues Guest Edited: (6 special issues)

Book Chapters: (23 Published Book Chapters)

Patent and Patent Disclosures: (22 Invention Disclosures, which includes 9 issued patents, and 13 more patent applications under review)

Selected Samples of Refereed Journal Papers (from a list of 161 refereed journal papers): N. Engheta, “Circuits with Light at Nanoscales: Optical Nanocircuits Inspired by Metamaterials”, Science, Vol. 317, pp. 1698-1702, September 21, 2007.

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B. Edwards, N. Engheta, and S. Evoy “Electric Tweezers: Experimental Studies of Positive Dielectrophoresis-Based Positioning and Orientation of a Nanorod,” in Journal of Applied Physics, Vol. 102, 024913 (5 pages) (2007). A. Alu and N. Engheta, “Higher-Order Resonant Power Flow Inside and Around Superdierctive Plasmonic Nanoparticles,” the Journal of Optical Society of America B, Feature Issue on Photonic Metamaterials, guest editors, V. M. Shalaev, A. Genack, E. Narimanov, Vol. 24, No. 10, pp. A89-A97, October 2007. A. Alu and N. Engheta, “Optical ‘Shorting Wires’”, Optics Express, Vol. 15, Issue 21, pp. 13773-13782, October 5, 2007 (The manuscript can be viewed at http://www.opticsinfobase.org/abstract.cfm?URI=oe-15-21-13773 ). A. Alu, A. Salandrino, and N. Engheta, “Coupling of Optical Lumped Nanocircuit Elements and Effects of Substrates,” Optics Express, Vol. 15, Issue 21, pp. 13865-13876, October 5, 2007. (The manuscript can be viewed at http://www.opticsinfobase.org/abstract.cfm?URI=oe-15-21-13865 .) A. Alu and N. Engheta, “Anamolies of Subdiffractive Guided-Wave Propagation along Metamaterial Nanocomponents,” Radio Science, special issue on “Analytical Scattering and Diffraction” guest edited by P. L. E. Uslenghi, Vol. 42, RS6S17, doi:10.1029/2007RS003691, 2007. J. Li and N. Engheta, “Core-Shell Nanowire Optical Antennas Fed by Slab Waveguides,” IEEE Transactions on Antennas and Propagation, Special Issue on Optical and THz and Antenna Technology, guest editors: Peter de Maagt and George Hansen, Vol. 55, No. 11, pp. 3018-3026, November 2007. A. Alu and N. Engheta, “Enhanced Directivity from Sub-Wavelength Infrared/Optical Nanoantennas Loaded with Plasmonic Materials or Metamaterials,” in IEEE Transactions on Antennas and Propagation, Special Issue on Optical and THz and Antenna Technology, guest editors: Peter de Maagt and George Hansen, Vol. 55, No. 11, pp. 3027-3039, November 2007. A. Salandrino, A. Alu, and N. Engheta, “Paralle l, Series, and Intermediate Interconnections of Optical Nanocircuit Elements. 1: Analytical Solutions,” Journal of Optical Society of America B, Vol. 24, No. 12, pp. 3007-3013, December 2007. A. Alu, A. Salandrino, and N. Engheta, “Parallel, Series, and Intermediate Interconnections of Optical Nanocircuit Elements. 2: Nanocircuit and Physical Interpretations,” Journal of Optical Society of America B, Vol. 24, No. 12, pp. 3014-3022, December 2007. J. Li, A. Salandrino, and N. Engheta, “Shaping the Beam of Light in Nanometer Scales: A Yagi-Uda Nanoantenna in Optical Domain,” Physical Review B, Vol. 76, 245403, December 6, 2007. M. Silveirinha and N. Engheta, “Theory of Supercoupling, Squeezing Wave Energy, and Field Confinement in Narrow Channels and Tight Bends Using Epsilon-Near-Zero Metamaterials,” Physical Review B, Vol. 76, 245109, December 10, 2007. B. Edwards, A. Alu, M. Young, M. Silveirinha, and N. Engheta, “Experimental Verification of Epsilon- Near-Zero Metamaterial Coupling and Energy Squeezing Using a Microwave Waveguide”, Physical Review Letters, Vol. 100, 033903, January 25, 2008. C. L. Holloway, D. C. Love, E. F. Kuester, A. Salandrino, and N. Engheta, “Sub-wavelength resonators: On the use of metafilm to overcome the lambda/2 size limit,” Institute of Engineerin and Technology (IET) Microwave, Antennas and Propagation, Vol. 2, No. 2, pp. 120-129, 2008. A. Alu and N. Engheta, “Multifrequency Optical Invisibility Cloak with Layered Plasmonic Shells,” Physical Review Letters, Vol. 100, No. 11, 113901, March 18, 2008. M. G. Silveirinha, A. Alu, J. Li, and N. Engheta, “Nanoinsulators and Nanoconnectors for Optical Nanocircuits,” Journal of Applied Physics, Vol. 103, 064305 (24 pages), 2008. A. Alu, M. Young, and N. Engheta, “Design of Nanofilters for Optical Nanocircuits”, Physical Review B, Vol. 77, No. 14, 144107 (12 pages) 2008. A. Alu and N. Engheta, “Tuning the Scattering Response of Optical Nanoantennas with Nanocircuit Loads”, in Nature Photonics, Vol. 2, pp. 307-310, May 2008. A. Alu and N. Engheta, “Robustness in Design and Background Variation in Metamaterials/Plasmonic Cloaking,” in Radio Science Special Section on the Electromagnetic Theory Symposium in

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Ottawa (July 2007), L. Shafai, A. Ishimaru, and M. Ando (guest editors), Vol. 43, RS4S01, (7 pages), 2008 doi:10.1029/2007RS003815. A. Alu and N. Engheta, “Dielectric Sensing in Epsilon-Near-Zero Narrow Waveguide Channels,” Physical Review B, Vol. 78, 045102 (5 pages), July 3, 2008. A. Alu and N. Engheta, “Input Impedance, Nanocircuit Loading, and Radiation Tuning of Optical Nanoantennas,” Physical Review Letters, Vol. 101, 043901 (4 pages), July 21, 2008. A. Alu, M. Silveirinha, and N. Engheta, “Transmission-Line Analysis of Epsilon-Near-Zero (ENZ)-Filled Narrow Channels” Physical Review E, Vol. 78, 016604 (10 pages), 23 July 2008. A. Alu and N. Engheta, “Light Squeezing through Arbitrarily Shaped Plasmonic Channels and Sharp Bends,” Physical Review B, Vol. 78, 035440 (6 pages), July 24, 2008. M. Silveirinha, A. Alu and N. Engheta, “IR and Optical Invisibility Cloak wit h Plasmonic Implants Based on Scattering Cancellation” Physical Review B, Vol. 78, 075107 (7 pages), August 11, 2008. A. Alu and N. Engheta, “Dynamical Theory of Artifical Optical Magnetism Produced by Rings of Plasmonic Nanoparticles,” Physical Review B, Vol. 78, 085112 (10 pages), August 11, 2008. (Invited Review) A. Alu and N. Engheta, “Plasmonic and Metamaterial Cloaking: Physical Mechanisms and Potentials,” Journal of Optics A: Pure and Applied Optics, Vol. 10, 093002 (17 pages), August 19, 2008. Selected in the 2008 Jounral of Optics Annual Highlights Collection. A. Alu and N. Engheta, “Dispersion Characteristics of Metamaterial Cloaking Structures,” Electromagnetics, Special Issue on “Metamaterials 2007”, guest editors: S. Zouhdi and S. Tretyakov, Vol. 28, No. 7, pp. 464-475, October 2008. A. Alu and N. Engheta, “Effects of Size and Frequency Dispersion in Plasmonic Cloaking,” Physical Review E, Rapid Communication, Vol. 78, 045602(R) (4 pages), October 2008. M. Silve ir inha, A. Alu, and N. Engheta, “Cloaking Mechanism with Antiphase Plasmonic Satellites”, Physical Review B, Vol. 78, 205109 (9 pages), November 2008. A. Alu and N. Engheta, “Hertzian Plasmonic Nanodimer as an Efficient Optical Nanoantenna,” Physical Review B, Vol. 78, 195111 (6 pages), November 2008. One of the figures of this manuscript has been selected for display on the front page of the e-version of journal Physical Review B in December 2008. A. Alu and N. Engheta, “Theory and Potentials of Muti-Layered Plasmonic Covers for Multi-Frequency Cloaking,” New Journal of Physics, Focus Issue on “Cloaking and Transformation Optics”, Guest Editors: Ulf Leonhardt and David R. Smith, Vol. 10, 115036 (15 pages), November 2008. V. Galdi, V. Pierro, G. Castaldi, and N. Engheta, “Genetically-Optimized Metasurface Pairs for Wideband Out-of-Phase Mutual Response,” IEEE Antennas and Wireless Propagation Letters, Vol. 7, pp. 788-791, 2008. A. Alu and N. Engheta, “Optical Nanoswitch: An Engineered Plasmonic Nanoparticle with Extreme Parameters and Giant Anisotropy” New Journal of Physics, Vol. 11 013026 (14 pages), 2009. G. Castaldi, I. Gallina, V. Galdi, A. Alu, and N. Engheta, “Cloak/anti-cloak Interactions,” Optics Express, Vol. 17, Issue 5, pp. 3101-3114, February 17, 2009. B. Edwards, A. Alu, M. Silveirinha and N. Engheta, “Reflectionless Sharp Bends and Corners in Waveguides Using Epsilon-Near-Zero Effects,” Journal of Applied Physics, Vol. 105, 044905 (4 pages), February 18, 2009. M. G. Silveirinha and N. Engheta, “Transporting an Image through a Subwavelength Hole,” Physical Review Letters, Vol. 102, 103902 (4 pages), March 13, 2009. A. Alu and N. Engheta, “The Quest for Magnetic Plasmons at Optical Frequencies,” Optics Express, Vol. 17, No. 7, pp. 5723-5730, March 25, 2009. J. McVay, A. Hoorfar, and N. Engheta, “Thin Absorbers Using Space-Filling-Curve Artif ic ial Magnet ic Conductors,” Microwave and Optical Technology Letters, Vol. 51, No. 3, pp. 785-790, March 2009. K. M Yemelyanov, J. McVay, A. Hoorfar, and N. Engheta, “Adaptive Polarization Contrast Techniques for Through-Wall Microwave Imaging Applications,” IEEE Transactions on Geoscience and

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Nader Engheta

Remote Sensing, special issue on Remote Sensing of Building Interior (M. Amin, and K. Sarabandi, guest editors), Vol. 47, No. 5, pp. 1362-1374, May 2009. J. Li, A. Salandrino, and N. Engheta, “Optical Spectrometer at the Nanoscale Using Optical Yagi-Uda Nanoantennas,” Physical Review B, Vol. 79, 195104 (5 pages), May 5, 2009. A. Alu and N. Engheta, “C loaking a Sensor,” Physical Review Letters, Vol. 102, 233901 (4 pages), June 8, 2009. This paper was selected as one of the Editors’ Suggestions in Phys. Rev. Letters. Moreover, this paper was also selected for highlighting for the online APS publication Physics. A. Alu and N. Engheta, “Guided Propagation along Quadrupolar Chains of Plasmonic Nanoparticles,” Physical Review B, Vol. 79, 235412 (12 pages), 2009. (Also indexed in the Virtual Journal of Nanoscale Science and Technology, Vol. 19, Issue 26, June 29, 2009.) D. A. Powell, A. Alu, B. Edwards, A. Vakil, Y. S. Kivshar, and N. Engheta, “Nonlinear control of tunneling through an epsilon-near-zero channel,” Physical Review B, Vol. 79, 245135 (5 pages), June 29, 2009. A. Alu and N. Engheta, “Boosting Molecular Fluorescence with a Plasmonic Nanolauncher,” Physical Review Letters, Vol. 103, 043902 (4 pages), July 21, 2009. A. Alu, P. A. Belov, and N. Engheta, “Parallel-Chain Optical Transmission Line for a Low-Loss Ultraconfined Light Beam,” Physical Review B Brief Report, Vol. 80, 113101, September 8, 2009. A. Alu and N. Engheta, “All-Optical Metamaterial Circuit Board at the Nanoscale,” Physical Review Letters, Vol. 103, 143902 (4 pages), September 29, 2009. B. Edwards, A. Alu, M. Silveirinha, and N. Engheta, “Experimental Verification of Plasmonic Cloaking at Microwave Frequencies with Metamaterials,” Physical Review Letters, Vol. 103, 153901 (4 pages), October 6, 2009. (Invited) A. Alu and N. Engheta, “On Certain Design Criteria for Nanoantennas in the Visible,” an invited manuscript to the special issue of Journal of Computational and Theoretical Nanoscience on the topic of “Functional Nanophotonics and Nanoelectromagnetics” (guest editors: Daniel Erni and Christophe Caloz), Vol. 6, No. 9, pp. 2009-2015, November 2009. One of the figures of this manuscript has been selected for display on the cover page of this issue of the journal. M. P. Nikiforov, S. C. Kehr, T.-H. Park, P. Milde, U. Zerweck, C. Loppacher, L. M. Eng, M. J. Therien, N. Engheta, and D. Bonnell, “Probing Polarization and Dielectric Function of Molecules with Higher Order Harmonics in s-NSOM,” Journal of Applied Physics, Vol. 106, 114307 (8 pages), 2009. A. Alu and N. Engheta, “Effect of Small Random Disorders and Imperfections on the Performance of Arrays of Plasmonic Nanoparticles,” New Journal of Physics, Vol. 12, 013015 (14 pages), 2010. A. Alu and N. Engheta, “Coaxial-to-Waveguide Matching with Epsilon-Near-Zero Ultranarrow Channels and Bends,” IEEE Transactions on Antennas and Propagation, Vol. 58, No. 2, pp. 328-339, February 2010. I. Gallina, G. Castaldi, V. Galdi, A. Alu, N. Engheta, “A general class of metamaterials transformation slabs,” Physical Review B, Vol. 81, No. 12, 125124 (10 pages), March 25, 2010. A. Alu and N. Engheta, “Comparison of Waveguiding Properties of Plasmonic Voids and Plasmonic Waveguides,” in the Special Issue of the Journal of Physical Chemistry C on the Martin Maskovits Festchrift, Vol. 114, pp. 7462-7471, 2010. A. Alu and N. Engheta, “Wireless at the nanoscale: Optical interconnects using matched nanoantennas,” Physical Review Letters, Vol. 104, 213902, May 24, 2010. A. Alu and N. Engheta, “How Does Zero Forward-Scattering in Magnetodielectric Nanoparticles Comply with Optical Theorem,” accepted for publication for the Special Issue of the Journal of Nanophotonics honoring the 70th Birthday of Professor Craig F. Bohren, in press.

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Nader Engheta

Question 9: Arguments in Support of the Nomination Nader Engheta is an internationally-renowned pioneer in the fields of metamaterials, plasmonic nano- optics, bio-inspired polarization imaging, and electrodynamics. His ground breaking and pioneering works in development and advancement of these fields have opened new vistas in these fields. He is one of the most innovative, creative and influent ia l scientists/leaders in these fields. His current research activities span a broad range of areas including metamaterials and plasmonics, nanooptics and nanophotonics, biologically-inspired sensing and imaging, miniaturized antennas and nanoantennas, physics and reverse- engineering of polarization vision in nature, mathematics of fractional operators, and physics of fields and waves phenomena. He has made significant contributions and major impacts in a variety of topics in these fie lds. He has been the originator and the pioneer of the new field of “Metactronics” (he coined this term), or in short “Metatronics”, which encompasses the concept of optical lumped nanocircuit elements in optics (i.e., “lumped nanophotonics”, in which one can have nanostructures that act as optical nanocapacitors, nanoinductors, and nanoresistors working with light instead of flow of electrons), that leads to an entirely new form of nanophotonics and metamaterial-inspired nanoelectronics and brings the mathematics, design, and machinery of circuit theory and design into the field of nano-optics with far-reaching and revolutionary potentials. This new paradigm of opt ica l nanocircuits, which merges the two fields of nano-opt ics with circuit theory, has the potential to lead to essentia lly unlimited future possibilities in nanocomputation, data storage, nanosystems, bio-optical interfacing and circuits, and nano-scale processing. As “electrons” have played the main role in the field of “electronics”, “photons” in “photonics”, and “spins” in “spintronics”, in the fie ld of “metatronics” pioneered and being developed by Nader Engheta the local opt ical f ields in nanostructures can play a major role in local information processing, leading to the future possibility of optical information processing at the nanoscale. Instead of drift of charged particles, which play important roles in electronics, here in metatronics it is the displacement currents that act as the main current of interest that can be manipulated and tailored at will using metamaterials. This can lead to a revolutionary and transformative departure from standard electronics. His vis ionary paper in Science on this topic of “Circuits wit h L ight at Nanoscales: Optical nanoc ircuits Inspired by Metamaterials” appeared in September 2007. His idea of lumped nanocircuits has generated a new paradigm and a new way of thinking about the nano-optics, and is leading to other exciting potential applications such as “wireless with light at the nanoscale” (Physical Review Lett 2010), nanotagging and nanobarcodes, tuning of optical nanoantennas (Nature Photonics, 2008) which may lead to exciting possibilities of using optical nanoantennas for nanoscale wireless communications at the level of biological entities, far-field subwavelength imaging (Phys. Rev. B. 2006), and nanospectrometers using nanoantennas (Phys. Rev. B. 2009), to name a few. (For his work on optical nanocircuits, he has been selected as Scientific American Magazine 50 Leaders in Science and Technology in 2006. Many press briefs and news articles are written about his Science paper and his Physical Review Letters papers on optical nanocircuits and they point to the transformative and revolutionary directions of his research. (The story about his work on metatronics has made the cover page of the March 3, 2008 issue of EE Times.) Just recently, he and his group have experimentally verified the concept of optical lumped circuit elements at Infrared wavelengths, thus realizing experimentally a set of parallel and series lumped circuit elements at wavelengths of 8-14 microns. He was among the first to originate the notion of metamaterial transparency/cloaking through his visionary and seminal work on electromagnetic cloaking/transparency using scattering-cancellation-based plasmonic layers published in Physical Review E in 2005, providing an entirely new camouflage technology and non-invasive probing with various poss ibilit ies. Many media news, press releases and news briefs have been written about his work on opt ical nanocircuits and EM transparency. His most recent work on “cloaking a sensor”, in Physical Review Letters in June 2009, has pushed the concept of cloaking to the next domains for sensors. The Science News has just recently written a news brief about his transformative work on cloaking a sensor, and APS Publication Physics highlighted this paper. He has made pioneering contributions in so many other areas of metamaterials, electromagnetics, bio-inspired imaging, fractional operators in EM, electromagnetic chirality, just to name a few. He has been elected Fellow of numerous organizations.

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Appendix 2 – page 1

INTERNATIONAL UNION OF RADIO SCIENCE

1. NAME OF CANDIDATE Gulyaev Yuri Vasilievich Last, First, Middle

PRESENT OCCUPATION: Director, Institute of Radioengineering and Electronics of the Position, Organization Russian Academy of Sciences (IRE RAS)

BUSINESS ADDRESS: 11/7, Mokhovaya st., Moscow, Russia, 125009, IRE RAS ...... HOME ADDRESS: 38-8-93, Zelinskogo st., Moscow, Russia, 117334

BIRTHDATE 18.09.1935 NATIONALITY: Russian SEX: male - female (Underline the appropriate)

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year

Moscow Phys. Tech. Inst. Moscow Eng. Diploma 1958 Moscow Phys. Tech. Inst. Moscow Ph.D 1962 IRE RAS Moscow D.Sci. 1970 Saint-Petersburg Electr. Tech. Institute Saint-Petersburg H. Professor 1989 Ioffe Phys. Tech. Institute Saint-Petersburg H. Professor 1995 Aviation and space Institute Samara H. Professor 2002 Saint-Petersburg Aviation and Space Institute Saint-Petersburg H. Professor 2010

3. PROPOSED CITATION (not more than thirty words) Outstanding scientist in the field of radio physics and electronics, one of the founders of acoustoelectronics, made valuable contribution to acoustooptics, spin-wave electronics and medical radioelectronics

4. NOMINATOR:

RUSSIAN NATIONAL COMMITTEE OF INTERNATIONAL SCIENTIFIC RADIO UNION (URSI RNC) ADRESS: Institute of Radioengineering and Electronics Russian Academy of Sciences (IRE RAS) 11/7, Mokhovaya st., Moscow, Center, 125009, Russia Tel: (007 495) 629 35 91 Fax: (007 495) 629 36 78 E-mail : [email protected]

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Appendix 2 – page 2 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

From (year) to (year) Name of Company/Institution Position and Responsibilities

1952 1958 Moscow Physics and Technology Student

Institute

1958 1960 Institute of Radioengineering and Post graduate student

Electronics of the Russian Academy

of Sciences (IRE RAS)

1960 1966 IRE RAS Scientist, Senior Scientist

1966 1972 IRE RAS Head of Laboratory

1972 1987 IRE RAS Deputy Director

1987 up to now IRE RAS Director

1970 up to now Moscow Physics and Technology Professor, Head of the Chair Institute of Solid State Electronics

Appendix 2 – page 3 6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS AWARDS: 1. State Prize of the USSR (1974) 2. European Physical Society Prize (1979) 3. State Prize of the USSR (1984) 4. State Prize of Russia (1992) 5. State Prize of Russia (2007) 6. Popov Gold Medal of RAS (1995) 7. IEEE Rayleigh Prize (2006) MEMBERSHIP: 8. Full member (Academician) of the Russian Academy of Sciences (RAS) since 1984 (since 1979 – Corresponding member). Member of the Presidium of RAS since 1992 up to now 9. Foreign member of Polish National Academy of Sciences (since 1988) - 3 -

10. Foreign member of Chinese Engineering Academy (since 2005) 11. Member of A.S.Popov Scientific and Technical Society of Radioengineering, Electronics and Telecommunications (since 1960 to now, since 1991 – President) 12. Member of IEEE since 1990 to now (since 2005 – Fellow), Chair of Russian section of IEEE 13. Member of URSI since 1985 up to now (since 2007 - President of Russian National Committee of URSI) 14. President of International and Russian Unions of Scientific and Engineering organizations (USEA) – since 1992 up to now 15. Vice-President of World Federation of Engineering Organizations (WFEO) since 1998 to 2003 16. President of A.M.Prokhorov Academy of Engineering Sciences of Russia since 2002 up to now.

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RUSSIAN ACADEMY OF SCIENCES RUSSIONAL NATIONAL COMMITTEE OF INTERNATIONAL SCIENTIFIC RADIO UNION (URSI)

Institute of Radioengineering and Electronics Russian Academy of Sciences (IRE RAS) 11/7, Mokhovaya st., Moscow, Center, 125009, Russia Tel: (007 495) 629 35 91 Fax: (007 495) 629 36 78 E-mail : [email protected]

The URSI Secretariat General Secretary Prof. P. Lagasse

Moscow, 19 August

Dear Professor Paul Lagasse,

The Russian National Committee of URSI has given careful consideration to Russian scientists as nominates for the URSI Awards and recommended Professor Yu.V. Gulyaev for awarding the Balthasar van der Pol Gold Medal. Yu. Gulyaev, academician of Russian Academy of Sciences, is outstanding scientist in many different branches of radioscience, electronics and computer science. He is one of the founders of new scientific and technical directions such as: acoustoelectronics, acoustooptics, spin-wave electronics. He opened and worked out the idea of using new fundamental type of surface acoustic waves in the piezoelectric materials known as the Bleustein-Gulyaev waves. These and other Yu. Gulyaev and his scientific school investigation results are used in new technologies of information processing and telecommunications. Yu. Gulyaev, together with his associates, carried out the precise measurements and dynamic mapping of physical fields and radiations of human body for the purpose of early medical diagnostics. Main scientific results obtained by Yu. Gulyaev are published in more than 600 scientific articles, 6 monographs and 50 patents. At present prof. Yu. Gulyaev is the Director of Kotelnikov Institute of Radioengineering and Electronics of Russian Academy of Sciences (IRE RAS) and - 5 - the Director of Institute nanotechnology microelectronics of the Russian Academy of Sciences -2-

Prof. Yu. Gulyaev is the President of URSI RNC. He is also the President of the Russian A.S. Popov Scientific and Technical Society of Radioengineering, Electronics and Telecommunications; Fellow of IEEE and Chair of the IEEE Russian Section, President of the International Union of Scientific and Technical Societies and Unions of CIS countries. Yu. Gulyaev is the Editor-in-Chief of the Scientific Journals: Radiotekhnica i Electronica = Radio and Communications Technology, Nonlinear Applied Dynamics, Radio Engineering, Biomedical Radioelectronics, Science and Technology in Industry. Yu. Gulyaev has two USSR and two Russia State Prizes, he was also awarded the Hewlett-Packard Europhysics Prize of European Physical Society for his works in the field of radioengineering and electronics. The URSI Russian National Committee believes Prof. Yu. Gulyaev is worth of being awarded the Balthasar van der Pol Gold Medal.

Sincerely yours,

Vice-President of the URSI RNC Prof. V. Lyubchenko

1. NAME OF CANDIDATE: Heyman, Ehud ...... Last, First, Middle

PRESENT OCCUPATION: ...... Position, Organization

Professor, Tel Aviv University, ISRAEL

BUSINESS ADDRESS: ......

Faculty of Engineering Tel Aviv University, Tel Aviv 69978, ISRAEL

HOME ADDRESS: ......

1 Maharal Street Tel Aviv 62481, ISRAEL

BIRTHDATE: 29 August 1952 NATIONALITY: Israel SEX:

male – female (Underline the appropriate)

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year

Tel Aviv University, Tel Aviv, Israel, B.Sc. Electrical Engineering, Summa Cum Laude (Valedictorian), 1977 Technion -- Israel Institute of Technology, Tel Aviv, Israel, M.Sc. Electrical Engineering, With Distinction, 1979 Polytechnic Institute of New York, Brooklyn, NY, USA, Ph.D. Electro-Physics, 1982. (Tutor: Professor L. B. Felsen.) [While at the Polytechnic Institute of New York, Ehud Heyman was a Rothschild Fellow, a Fulbright Fellow, and a Hebrew Technical Institute Fellow.]

3. PROPOSED CITATION (not more than thirty words)

For developing mathematical tools to analyze the generation, propagation and scattering of beam-shaped electromagnetic fields, and their engineering applications.

4. NOMINATOR: Professor Adrianus T. de Hoop ADDRESS: Laboratory of Electromagnetic Research, Faculty of Electrical Engineering, Mathematics and Computer Science, Delft University of Technology, Mekelweg 4, 2628 CD Delft, the Netherlands PHONE: +31 (0)15-2785203 ...... FAX: ...... E-MAIL : [email protected]

5 PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

1996 – present: Tel Aviv University, Tel Aviv, Israel, Professor

1990 – 1996: Tel Aviv University, Tel Aviv, Israel, Associate Professor

1986 – 1990: Tel Aviv University, Tel Aviv, Israel, Senior Lecturer

1983 – 1986: Tel Aviv University, Tel Aviv, Israel, Lecturer

1982 – 1983: Polytechnic Institute of New York, Brooklyn NY, USA,

Post-Doctoral Fellow

FURTHER PROFESSIONAL EXPERIENCE

1984 – 1990: Consultant, Microwave Research Institute, Polytechnic Institute of New York , Brooklyn NY, USA

1991 – 1992: Visiting Research Fellow, Northeastern University, Boston, MA, USA

1991 – 1992: Visiting Research Fellow, Massachustetts Institute of Technology, Cambridge MA, USA 1991 – 2001: Consultant, A. J. Devaney Associates, Inc., Boston, MA, USA

1992: Visiting Professor, Chuo University, Tokyo, Japan

1993, 1995, 1997, 1999: Visiting Research Fellow, Northeastern University, Boston, MA, USA

1994: Visiting Professor, Eindhoven University of Technology, Eindhoven, the Netherlands

6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

1977: Tel-Aviv University Rector's Honor List 1978 B.Sc. Summa Cum Laude, Valedictorian 1979 Rothschild Fellowship 1979 Fulbright Fellowship 1981 & 1982 Hebrew Technical Institute Scholarship 1985 B. de Rothschild Grant for Young Distinguished Researchers 2000 Fellow of the IEEE - Antennas and Propagation Society

Fellow, Institute of Electrical and Electronics Engineers (IEEE): Antennas and Propagation (AP) Society Member, The Israeli National Committee for the International Union of Radio Science (URSI) Chairman (since 1999), The Israeli National Committee for the International Union of Radio Science (URSI) Chairman of Commission B (1984-1999), The Israeli National Committee for the International Union of Radio Science (URSI) Member, Electromagnetics Academy

CONVENOR, ORGANIZER, TECHNICAL PROGRAM COMMITTEE MEMBER OF NUMEROUS URSI ACTIVITIES

1994 – present: Associate Editor of the IEEE Press Series on Electromagnetic Wave Theory 1996 – 1999: Associate Editor of IEEE Transactions on Antennas and Propagation 2007: Guest Editor (with S. Maci and H. L. Bertoni), IEEE Transactions on Antennas and Propagation, Special Issue on Electromagnetic Waves in Complex Environments: A Tribute to Leopold B. Felsen, , Vol. AP-55(6) Parts ! and II, June 2001 2007 – 2008: Associate Editor of IEEE Transactions on Antennas and Propagation

7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex – maximum 5 pages)

- Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions.

0. E. Heyman, “Pulsed beam solutions for propagation and scattering problems,” in Scattering: Scattering and Inverse Scattering in Pure and Applied Science, R.Pike and P.Sabatier, eds., Academic Press, 1,Chap.1.5.4, 295-315, 2002. 1. E. Heyman, “The focus wave mode: A dilemma with causality,” IEEE Trans. Antennas Propagat., AP-37, 1604-1608, 1989. 2. E. Heyman, “Complex source pulsed beams: Propagation scattering and applications,” in Directions in electromagnetic wave modeling, H.L.Bertoni and L.B. Felsen eds., Plenum Press, 1991, 87-100. 3. E. Heyman, “Pulsed beam propagation in can inhomogeneous medium,” IEEE Trans. Antennas Prop,, AP-42, 311-319. 1994. 4. E. Heyman, “Transient plane wave spectrum representation for radiation from volume source distribution,” J. Math. Phys., 37, 658-681, 1996. 5. J. Oz and E. Heyman, “Modal theory for the two-frequency mutual coherence function in random media. Beam waves,” Waves in Random Media, 8, 159-174, 1998. 6. R.W. Ziolkowski and E. Heyman, “Wave propagation in media having negative permittivity and permeability,” Phys. Rev. E, 64(5): DOI: 10.1103/Phys Rev E.64.056625, 2001 7. G. Gordon, E. Heyman, and R. Mazar, “Phase space beam summation analysis of rough surface waveguide,” J. Acoustical Soc. Am., 117, 1922-1932, 2005. 8. M. Katsav and E. Heyman, “A beam summation representation for 3-D radiation from a line source distribution,” IEEE Trans. Antennas Propagat., AP-56(2), 602-605, 2008. doi:10.1109/TAP.2007.913173 9. Y Gluck and E. Heyman, “Pulsed beams expansion algorithm for transient radiation. A basic algorithm and a standard-pulsed-beams algorithm,” IEEE Trans. Antennas Propagat., to be published

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT

X Balthasar van der Pol Gold Medal

John Howard Dellinger Gold Medal

Appleton Prize

Booker Gold Medal

Issac Koga Gold Medal

9. ARGUMENTS IN SUPPORT OF THE NOMINATION (Limit to this page)

Professor Ehud Heyman is the internationally leading scientist in the mathematical modeling of the behavior of beam-shaped electromagnetic and acoustic waves. The principal tool to describe the generation, propagation and scattering of this type of field is the relevant ‘beam’, which is a wave constituent that lies in between a pencil beam of geometrical rays and the more all-directional field distributions devoid of any particular geometric shape. Standardly, so-called Gaussian beams are used for this purpose, but these have a variety of mathematical and physical disadvantages. The beams with a so-called ‘complex source point’ overcome these disadvantages. Exactly this latter description has extensively been employed by Professor Heyman to analyze the behavior of beam-structured fields in a variety of engineering configurations. Numerous publications in the international literature prove his ingenuity in this field of application. (See, for a broad indication, below.)

Electromagnetic radiation and antennas Propagation and scattering in the time and frequency domains; Ray and Beam fields in homogeneous and in inhomogeneous medium; Short-pulse fields Spectral, asymptotic and mode techniques in the time and frequency domains; Local spectrum and phase space techniques Pulsed beams and directed energy transfers Targets identification and inverse scattering Imaging techniques and Synthetic Aperture Radar Applications of Finite Difference Time Domain (FDTD) methods Propagation in random medium

Chapters in Books

1. L.B. Felsen and E. Heyman, “Hybrid ray mode analysis of transient scattering problems,” in Handbook on Acoustic, Electromagnetic and Elastic Wave Scattering - Low and High Frequency Asymptotics, V.K. and V.V. Varadan, eds., Elsevier Science Publishers B.V., North Holland, The Netherlands, 1986, Chap.5, 403-512. 2. E. Heyman, G. Friedlander and L.B. Felsen, “Ray-mode analysis of complex resonances of an open cavity,” in Radar Cross Section of Complex Objects, W.R. Stone ed., IEEE Press, 1990, 383- 398. 3. E. Heyman and T. Melamed, “Space-time representation of ultra-wideband signals,” in Advances in Imaging and Electron Physics, P.W. Hawkes ed., 103, 1-66, Academic Press, 1998. 4. E. Heyman, “Pulsed beam solutions for propagation and scattering problems,” in Scattering: Scattering and Inverse Scattering in Pure and Applied Science, R.Pike and P.Sabatier, eds., Academic Press, 1,Chap.1.5.4, 295-315, 2002. Articles 10. E. Heyman and L.B. Felsen, “Creeping waves and resonances in transient scattering by smooth convex objects,” IEEE Trans. Antenna. Propagat., AP-31, 426-437, 1983. 11. E. Heyman and L.B. Felsen, “Evanescent waves and complex rays for modal propagation in curved open waveguides,” SIAM J. Appl. Math.,43, 855-884, 1983. 12. E. Heyman and L.B. Felsen, “High frequency fields in the presence of curved dielectric interface,” IEEE Trans. Antenna. Propagat., AP-32, 969-978, 1984. 13. E. Heyman, “On the tunneling hypothesis for ray reflection and transmission at a curved dielectric boundary,” IEEE Trans. Antenna Propagat., AP-32, 978-986, 1984. 14. E. Heyman and L.B. Felsen, “Non-dispersive approximation for transient ray fields in an inhomogeneous medium,” in Hybrid Formulation of Wave Propagation and Scattering, NATO ASI, Series E, Vol. 86, Nijhoff Pub. Co., The Hague, Netherlands, 1984, 269-284. 15. E. Heyman and L.B. Felsen, “Wavefront interpretation of SEM resonances, turn-on times and entire functions,” in Hybrid Formulation of Wave Propagation and Scattering, NATO ASI, Series E, Vol. 86, Nijhoff Pub. Co., The Hague, Netherlands, 1984, 253-267. 16. E. Heyman and L.B. Felsen, “Non dispersive closed form approximation for transient propagation and scattering of ray fields,” Wave Motion, 7, 335-358, 1985. 17. E. Heyman and L.B. Felsen, “A wavefront interpretation of the Singularity Expansion Method,” IEEE Trans. Antennas Propagat., AP-33,706-718, 1985. 18. E. Heyman and L.B. Felsen, “Travelling waves and SEM representations for transient scattering by a circular cylinder,” J. Acoust. Soc. Am., 79, 230-238, 1986. 19. E. Heyman and L.B. Felsen, “Propagating pulsed beam solution by complex source parameter substitution,” IEEE Trans. Antennas Propagat., AP-34, 1062-1065, 1986. 20. E. Heyman and L.B. Felsen, “Weakly dispersive spectral theory of transients (STT). Part I: Formulation and interpretation,” IEEE Trans. Antennas Propagat., AP-35, 80-86, 1987. 21. E. Heyman and B.Z. Steinberg, “A spectral analysis of complex source pulsed beams,” J. Opt. Soc. Am. A, 4, 473-480, 1987. “Reply to comment,” J. Opt. Soc. Am. A, 5, 757, 1988. 22. E. Heyman and L.B. Felsen, “Weakly dispersive spectral theory of transients (STT). Part II: Evaluation of the spectral integral,” IEEE Trans. Antennas Propagat., AP-35, 574-580, 1987. 23. E. Heyman, “The Hybrid wavefront-resonance method,” in Theoretical Aspects of Target Classification, L.B. Felsen, ed., AGARD Lecture Series No. 152, 4.1-4.24, 1987. 24. E. Heyman, B.Z. Steinberg and L.B. Felsen, “Spectral analysis of focus wave modes (FWM),” J. Opt. Soc. Am. A, 4, 2081-2091, 1987. 25. E. Heyman, “Weakly dispersive spectral theory of transients (STT), Part III: Applications,” IEEE Trans. Antennas Propagat., AP 35, 1258-1266, 1987. 26. E. Heyman and L.B. Felsen, “Real and complex spectra - an alternative view of WKBJ seismograms,” Geophys. J. Roy. Astro. Soc., 91, 1087-1126, 1987. 27. L.B. Felsen and E. Heyman, “Discretized beam methods for focused radiation from distributed aperture,” SPIE Proc., 873 (Microwaves and Particle Beam Sources and Propagation), 320-328, 1988. 28. R. Kastner, E. Heyman and A. Saban, “Spectral domain iterative analysis of single and double layered microstrip antennas using the conjugate gradient algorithm,” IEEE Trans. Antennas Propagat., AP-36, 1204- 1212, 1988. 29. B.Z. Steinberg, E. Heyman and L.B. Felsen, “Phase space methods for radiation from apertures,” SPIE Proc., 1061 (Microwaves and Particle Beam Sources and Directed Energy Concepts), 1989. 30. E. Heyman, R. Ianconescu and L.B. Felsen, “Pulsed beam interaction with propagation environments: Canonical examples of reflection and diffraction,” SPIE Proc., 1061 (Microwave and Particle Beam Sources and Directed Energy Concepts), 1989. 31. E. Heyman, “Complex source pulsed beam expansion of transient radiation,” Wave Motion, 11, 337-349, 1989. 32. E. Heyman, G. Friedlander and L.B. Felsen, “Ray-mode analysis of complex resonances of an open cavity,” The Proceedings of the IEEE, 77, 780-787, 1989. (Invited). 33. E. Heyman and L.B. Felsen, “Complex source pulsed beam fields,” J. Opt. Soc. Am. A, 6, 806-817, 1989. 34. E. Heyman, “The focus wave mode: A dilemma with causality,” IEEE Trans. Antennas Propagat., AP-37, 1604-1608, 1989. 35. E. Heyman, B.Z. Steinberg and R. Ianconescu, “Electromagnetic complex source pulsed beam fields,” IEEE Trans. Antennas Propagat., AP-38, 957-963, 1990. 36. E. Heyman and R. Ianconescu, “Pulsed beam reflection and transmissions at a dielectric interface: part I. Two dimensional fields,” IEEE Trans. Antennas Propagat., AP-38, 1791-1800, 1990. 37. B.Z. Steinberg, E. Heyman and L.B. Felsen, “Phase space beam summation for time-harmonic radiation from large apertures,” J. Opt. Soc. Am. A, 8, 41-59 1991. 38. E. Heyman, “Complex source pulsed beams: Properties and applications,” Radio Science, 26, 237-248, 1991, (Invited). 39. B.Z. Steinberg, E. Heyman and L.B. Felsen, “Phase space methods for radiation from large apertures,” Radio Science, 26, 219-222, 199, (Invited). 40. B.Z. Steinberg, E. Heyman and L.B. Felsen, “Phase space beam summation for time dependent radiation from apertures: Continuous parametrization,” J. Opt. Soc. Am., 8, 943-958, 1991. 41. B.Z. Steinberg and E. Heyman, “Phase space beam summation for time dependent radiation from large apertures: Discretized parametrization,” J. Opt. Soc. Am. A, 8, 959-966, 1991. 42. I. Beracha and E. Heyman, “Hermite pulsed beam expansion of well collimated pulsed radiation,” Proc. SPIE, (Intense Microwave and Particle Beams IIII), 1629, 352-357, 1992. 43. E. Heyman, “Complex source pulsed beams: Propagation scattering and applications,” in Directions in electromagnetic wave modeling, H.L.Bertoni and L.B. Felsen eds., Plenum Press, 1991, 87-100. 44. T. Melamed and E. Heyman, “Phase-Space beam summation for time harmonic and time-dependent radiation from extended apertures: 3D formulation,” Proc. SPIE, Intense Microwave and Particle Beams III, 1629, 336- 357, 1992. 45. E. Heyman and I. Beracha, “Complex multipole pulsed beams and Hermite pulsed beams: A novel expansion scheme for transient radiation from well collimated apertures,” J. Opt. Soc. Am. A, 9, 1779-1793, 1992. 46. G. Friedlander and E. Heyman, “Hybrid wavefront-resonance representation for transient scattering by an open cavity. Part I: Formulation,” J. Electromagn. Waves Applic., 7, 355-372, 1993. 47. G. Friedlander and E. Heyman, "Hybrid wavefront-resonance representation for transient scattering by an open cavity. Part II: Numerical results and interpretation,” J. Electromagn. Waves Applic., 7, 561-576, 1993. 48. E. Heyman and G. Friedlander, “Hybrid wavefront-resonance representation for transient scattering by an open cavity. Part III: Analytical models for the late time oscillations,” J. Electromagn. Waves Applic., 7, 703-715, 1993. 49. B.Z. Steinberg and E. Heyman, “The local Radon transform and variable scale resolution with application to time-dependent radiation” , SIAM J. Appl. Math., 53, 381-400, 1993. 50. E. Heyman, R. Strachielevitz and D. Koslof, “Pulsed beam reflection and transmission at a planar interface: Exact solutions and approximate local models,” Wave Motion, 18, 315-343, 1993. 51. E. Heyman, “On general wavepacket solutions of the time dependent wave equation in homogeneous and inhomogeneous media,” in Ultra-Wideband, Short-pulse Electromagnetics, H.L. Bertoni, L. Carin and L.B. Felsen eds., Plenum Press, NY, 1993, 241-250. 52. E. Heyman, “Pulsed beam propagation in can inhomogeneous medium,” IEEE Trans. Antennas Prop,, AP-42, 311-319. 1994. 53. E. Heyman and T. Melamed, “Certain consideration in aperture synthesis for ultra wideband/short-pulsed fields,” IEEE Trans. Antennas Propagat., AP-42, 518-525, 1994. 54. R. Ianconescu and E. Heyman, “Pulsed field diffraction by a perfectly conducting wedge: A spectral theory of transient (STT) analysis,” IEEE Trans. Antennas Propagat., AP-42, 781-789, 1994. 55. R. Ianconescu and E. Heyman, “Pulsed beam diffraction by a perfectly conducting wedge. Exact Solution,” IEEE Trans. Antennas Propagat., AP-42, 1377-1385, 1994. 56. E. Heyman and L.B. Felsen, “Comments on: `Nondispersive waves - interpretation and causality” , IEEE Trans. Antennas and Propagat., AP-42, 1668-1670, 1994. 57. E. Heyman and R. Ianconescu, “Pulsed beam diffraction by a perfectly conducting wedge. Local scattering models,” IEEE Trans. Antennas Propagat. , AP-43, 519-528, 1995. 58. Y. Leviatan, Z. Baharav and E. Heyman, “Analysis of electromagnetic scattering using arrays of fictitious sources,” IEEE Trans. Antennas and Propagat., AP-43, 1091-1098, 1995. 59. H. Sato H. Shirai and E. Heyman, “Transient impulsive response from an interface between two media - Spectral theory of transient analysis,” IEICE Trans. on Electronics, Series C-I, J78, 439-447, 1995. 60. E.A. Marengo, F. Anthony, A.J. Devaney and E. Heyman, “Radiation characteristics of collimated, ultrawideband, volume sources,” in Ultra-Wideband, Short-pulse Electromagnetics II, L. Carin, and L.B. Felsen, eds., Plenum Press, NY, 1995, 321-330. 61. E. Heyman, “Transient plane wave spectrum representation for radiation from volume source distribution,” J. Math. Phys., 37, 658-681, 1996. 62. E. Heyman and A.J. Devaney, “Time-dependent multipoles and their application for transient radiation,” J. Math. Phys., 37, 682-692, 1996. 63. J. Oz and E. Heyman, “Modal solution to the plane wave two-frequency mutual coherence function in random media,” Radio Science (invited), 31, 1907-1918, 1996. 64. T. Melamed, Y. Ehrlich and E. Heyman, “Short pulse inversion of inhomogeneous media: A time-domain diffraction tomography,” Inverse Problems, 12, 977-993, 1996. 65. J. Oz and E. Heyman, “Modal theory for the two-frequency mutual coherence function in random media. General solution and plane wave solution,” Waves in Random Media, 7, 79-93, 1997. 66. J. Oz and E. Heyman, “Modal theory for the two-frequency mutual coherence function in random media. Plane wave solution (Part II),” Waves in Random Media, 7, 95-106, 1997. 67. T. Melamed and E. Heyman, “Spectral analysis of time-domain diffraction tomography,” Radio Science (invited), 32, 593-604, 1997. 68. E.A. Marengo, A.J. Devaney and E. Heyman, “Analysis and characterization of ultrawideband scalar volume sources and the fields they radiate,” IEEE Trans. Antennas and Propagat., AP-45, 1098-1106, 1997. 69. A. Shlivinski, E. Heyman and R. Kastner, “A unified antenna parameterization in the time and frequency domains,” IEEE Trans. Antennas and Propagat., AP-45, 1140-1149, 1997. 70. B. Fidel, E. Heyman, R. Kastner and R.W. Ziolkowski, “Hybrid ray-FDTD moving window approach to pulse propagation,” J. Comp. Phys. D., 138, 480-500, 1997. 71. J. Oz and E. Heyman, “Modal theory for the two-frequency mutual coherence function in random media. Beam waves,” Waves in Random Media, 8, 159-174, 1998. 72. J. Oz and E. Heyman, “Wigner Ville distribution for pulsed propagation in random media,” Waves in Random Media, 8, 175-191, 1998. 73. E.A. Marengo, A.J. Devaney and E. Heyman, “Analysis and characterization of ultrawideband scalar volume sources and the fields they radiate: Part II - square pulse excitation,” IEEE Trans. Antennas and Propagat., AP- 46, 243-250, 1998. 74. A. Shlivinski and E. Heyman, “Time domain near field analysis of short pulse antennas. Part I: Spherical wave (multipole) expansion,” IEEE Trans. Antennas and Propagat., AP-47, 271-279, 1999. 75. A. Shlivinski and E. Heyman, “Time domain near field analysis of short pulse antennas. Part II: Reactive energy and the antenna $Q$,” IEEE Trans. Antennas and Propagat., AP-47, 280-286, 1999. 76. G.A. Tsihrintzis, A.J. Devaney and E Heyman, “Estimation of object location from short pulse scatter data,” IEEE Trans. Image Processing, 8, 996-1001, 1999. 77. T. Melamed, E. Heyman and L.B. Felsen, “Local spectral analysis of short-pulse-excited scattering from weakly inhomogeneous media: Part I - Forward scattering,” IEEE Trans. Antennas and Propagat., AP-47, 1208-1217, 1999. 78. T. Melamed, E. Heyman and L.B. Felsen, “Local spectral analysis of short-pulse-excited scattering from weakly inhomogeneous media: Part II - Inverse scattering,” IEEE Trans. Antennas and Propagat., AP-47, 1218-1227, 1999. 79. A. Shlivinski and E. Heyman, “Energy considerations in space-time synthesis of collimated pulsed apertures,” in Ultra-Wideband, Short-pulse Electromagnetics 4, E.Heyman, J.Shiloh and B.Mandelbaum, eds., Plenum Press, NY, 1999, 65-76. 80. B.P. de Hon, E. Heyman and L.B. Felsen, “Spectral alternatives for the synthesis of short-pulse wavefields in waveguides,” in Ultra-Wideband, Short-pulse Electromagnetics 4, E.Heyman, J.Shiloh and B.Mandelbaum, eds., Plenum Press, NY, 1999, 289-300. 81. A. Arev, E. Heyman and B-Z. Steinberg, “A mixed time-frequency-scale analysis of the hybrid wavefront resonance theory,” in Ultra-Wideband, Short-pulse Electromagnetics 4, E.Heyman, J.Shiloh and B.Mandelbaum, eds., Plenum Press, NY, 1999, 361-370. 82. E. Heyman, V. Lomakin, and Gerald Kaiser, “Physical source realization of complex source pulsed beams,” J. Acoust. Soc. Am, 107, 1880-1891, 2000. 83. Y. Pemper, V. Lomakin, E. Heyman, R. Kastner and R.W. Ziolkowski, “Moving coordinate frame FDTD analysis of long range tracking of pulsed fields in graded index waveguides,” Progress in Electromagnetic Research (PIER). 26, 135-166, 2000. Extended Abstract: J. Electromagn. Waves Applic., 14, 493-496, 2000. 84. Y. Pemper, E. Heyman, R. Kastner and R.W. Ziolkowski, “Hybrid ray-FDTD moving coordinate frame approach for long range tracking of collimated wavepackets,” Progress in Electromagnetic Research (PIER). 30, 1-32, 2001. Extended Abstract: J. Electromagn. Waves Applic., 14, 1115-1117, 2000. 85. J. Pasvolsky, E. Heyman, R. Kastner and A. Boag, “Electromagnetic analysis of an antenna embedded in a composite environment,” IEEE Trans. Antennas Propagat., AP-49, 681-687, 2001 . 86. R.Holtzman, R.Kastner, E.Heyman and R.W. Ziolkowski, “Stability analysis of the green's function method (GFM) used as an ABC for arbitrarily-shaped boundaries,” IEEE Trans. Antennas Propagat., AP-50, 1017- 1029, 2002 87. E. Heyman and L.B. Felsen, “Gaussian beam and pulsed beam dynamics: Complex source and spectrum formulations within and beyond paraxial asymptotics,” J. Opt. Soc. Am. A, 18, 1588-1611, 2001. 88. A. Shlivinski, E. Heyman and A.J. Devaney, “Time domain plane wave to multipole transform,” J. Mat. Phys., 42, 5915-5919, 2001. 89. R.W. Ziolkowski and E. Heyman, “Wave propagation in media having negative permittivity and permeability,” Phys. Rev. E, 64(5): DOI: 10.1103/Phys Rev E.64.056625, 2001 90. A. Shlivinski and E. Heyman, “Discrete array representation of a continuous space-time source distributions,” Electrik, Special issue on Electromagnetic Problems & Numerical Simulation Techniques, 10(2), 257-271, 2002, invited. 91. A. Shlivinski and E. Heyman, “A unified kinematic theory of transient array,” in Ultra-Wideband, Short-pulse Electromagnetics 5, P.D Smith and S.R. Cloude Eds., Kluwer Academic/Plenum Publishers, NY, 2002, 11-20. 92. A. Shlivinski and E. Heyman, “Analytical methods for antenna analysis and synthesis in the time domain,” in Ultra-Wideband, Short-pulse Electromagnetics 5, P.D Smith and S.R. Cloude Eds., Kluwer Academic/Plenum Publishers, NY, 2002, 327-334. 93. V. Lomakin, B. Z. Steinberg and E. Heyman, “UWB analysis of EM fields in complex laminates: An MRA homogenization approach,” in Ultra-Wideband, Short-pulse Electromagnetics 5, P.D Smith and S.R. Cloude Eds., Kluwer Academic/Plenum Publishers, NY, 2002, 67-74. 94. D. Lugara, C. Letrou, A. shlivinski, E. Heyman, and A. Boag, “The frame based Gaussian beam summation method: theory and application,” Radio Science, 38(2), VIC27/1-15, 2003. doi:10.1029/2001RS002593. 95. A. Shlivinski, E. Heyman, A. Boag, and C. Letrou, “Frame-based beam-summation algorithms for ultra wideband radiation from extended apertures. Part I: Formulations in the multi-frequency domain,” in Ultra- Wideband, Short-pulse Electromagnetics 6, E.L.Mokole, M.Kragalott and K.R.Gerlach eds., Kluwer Academic Plenum Publishers NY, 2003, 101-112. 96. A. Shlivinski, E. Heyman, A. Boag, and C. Letrou, “Frame-based beam-summation algorithms for ultra wideband radiation from extended apertures. Part II: Time domain formulation,” in Ultra-Wideband, Short- pulse Electromagnetics 6, E.L.Mokole, M.Kragalott and K.R.Gerlach eds., Kluwer Academic / Plenum Publishers NY, 2003, 113-122. 97. V. Lomakin, B.Z. Steinberg and E.Heyman, “Multi-resolution homogenization (MRH) for short pulse field and fault interrogation in complex laminates,” in Ultra-Wideband, Short-pulse Electromagnetics 6, E.L.Mokole, M.Kragalott and K.R.Gerlach eds., Kluwer Academic Plenum Publishers NY, 2003, 203-214. 98. V. Lomakin, B.Z. Steinberg, E. Heyman and L.B. Felsen, “Multi-resolution homogenization of field and network formulations for multi-scale laminate dielectric slabs, I: Field theory,” IEEE Trans. Antennas Propagat., AP-51, 2761-2777, 2003. 99. A. Shlivinski, E. Heyman, A. Boag and C. Letrou, “A phase-space beam summation formulation for wideband radiation, IEEE Trans. Antennas Propagat., AP-52, 2042-2056, 2004. 100. A. Shlivinski, E. Heyman and A. Boag, “A phase-space beam summation formulation for ultra wideband radiation. Part II - A multi-band scheme,” IEEE Trans. Antennas Propagat., AP-53, 948-957, 2005. 101. G. Gordon, E. Heyman, and R. Mazar, “A phase-space Gaussian Beam summation representation of rough surface scattering,” J. Acoustical Soc. Am., 117, 1911-1921, 2005. 102. G. Gordon, E. Heyman, and R. Mazar, “Phase space beam summation analysis of rough surface waveguide,” J. Acoustical Soc. Am., 117, 1922-1932, 2005. 103. A. Shlivinski, E. Heyman and A. Boag, “A pulsed beam summation formulation for short pulse radiation based on windowed Radon transform (WRT) frames,” IEEE Trans. Antennas Propagat., AP-53, 3030-3048, 2005. 104. M. Katsav, A. Shlivinski, and E. Heyman, “The UWB Beam summation algorithms for focusing near curved interfaces,” Radio Science 40(6), RS6S11, doi: 10.1029/2004RS003204, , 2005. (invited to the special issue dedicated to the URSI 2004 Triennium Symposium on Electromagnetic Theory). 105. R. Holtzman, R. Kastner, E. Heyman, and R. W. Ziolkowski, “Ultra-wideband cylindrical antenna design using the Green’s function method (GFM) as an absorbing boundary condition (ABC) and the radiated field propagator in a genetic optimization,” Microwave Opt. Tech. Lett. 48(2), 348-354, 2006, doi:10.1002/mop 106. T. Heilpern, E. Heyman, and V. Timchenko, “A beam summation algorithm for wave radiation and guidance in stratified media,” J. Acoust. Soc. Am., 121(4), 1856-1864, 2007. 107. M. Katsav and E. Heyman, “Phase space Gaussian beam summation analysis of half plane diffraction,” IEEE Trans. Antennas Propagat.. AP-55, 1535-1545, 2007 (invited). 108. M. Katsav and E. Heyman, “Gaussian beam summation representation of a two-dimensional Gaussian beam diffraction by a half plane,” IEEE Trans. Antennas Propagat., AP-55(8), 2247-2257, 2007. 109. M. Katsav and E. Heyman, “A beam summation representation for 3-D radiation from a line source distribution,” IEEE Trans. Antennas Propagat., AP-56(2), 602-605, 2008. doi:10.1109/TAP.2007.913173 110. Y. Shlivinski and E. Heyman, “Physical models for polarimetric SAR analysis,” IEEE Trans. Antennas Propagat., AP-56(8), 2664-2672, 2008. doi:10.1109/TAP.2008.927499 111. A. Shlivinski and E. Heyman, “Windowed Radon transform frames,” Applied and Computational Harmonic Analysis (ACHA), 26, 322-343, 2009. doi:10.1016/j.acha.2008.07.003 112. M. Katsav and E. Heyman, “Gaussian Beam Summation Representation of Half Plane Diffraction: a Full 3D Formulation,” IEEE Trans. Antennas Propagat., AP-57(4), 1081-1094, 2009. doi:10.1109/TAP.2009.2013436 113. Y. Kaganovsky and E. Heyman, “Wave analysis of Airy beams,” Optics Express, 18 (8), 8440-8452, 2010. doi:10.1364/OE.18.008440 http://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-18-8-8440 114. S. Malevsky, E. Heyman and R. Kastner “Source decomposition as a diakoptic boundary condition in FDTD with Reflecting External Regions,” IEEE Trans. Antennas Propagat., in press, 2010. 115. Y Gluck and E. Heyman, “Pulsed beams expansion algorithm for transient radiation. A basic algorithm and a standard-pulsed-beams algorithm,” IEEE Trans. Antennas Propagat., to be published

Appendix 2 – page 1

INTERNATIONAL UNION OF RADIO SCIENCE

1. NAME OF CANDIDATE: HOEFER, Wolfgang J. R. Last, First, Middle

PRESENT OCCUPATION: Principal Scientist Position, Organization Institute of High Performance Computing 1 Fusionopolis Way, #16-16 Connexis Singapore 138632

BUSINESS ADDRESS: Institute of High Performance Computing 1 Fusionopolis Way, #16-16 Connexis Singapore 138632 [email protected]

HOME ADDRESS: 7, One-North Gateway #05-21 Singapore 138642 ......

BIRTHDATE 6 Feb. 1941 NATIONALITY: German SEX: male - female (Underline the appropriate)

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year

RWTH Aachen Aachen, Germany Diplom-Ingenieur 1965 Université de Grenoble Grenoble, France Docteur-Ingénieur 1968 Technische Universität München Munich, Germany Dr.-Ing h.c. (H) 2007

3. PROPOSED CITATION (not more than thirty words) ...... For pioneering contributions to computational time domain methods in electromagnetics, in particular the Transmission Line Matrix (TLM) method......

4. NOMINATOR: Christophe Caloz ADDRESS: École Polytechnique de Montréal Building Lassonde, Office M6025 2500, ch. de Polytechnique Montréal (Québec), H3T 1J4, Canada PHONE: +1 (514) 340-4711, ext. 3326 FAX: +1 (514) 340-5892 E-MAIL : [email protected]

Appendix 2 – page 2 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

From (year) to (year) Name of Company/Institution Position and Responsibilities

Full-Time Appointments

2009 Present IHPC, A-Star, Singapore Principal Scientist, Res. Direction

2006 2009 University of Victoria, Canada Professor Emeritus, Research in ECE

1992 2006 University of Victoria, Canada NSERC Res. Chair, Teach. & Res.

1992 1995 University of Ottawa, Canada Adjunct Professor, Research

1980 1992 University of Ottawa, Canada Professor, Teaching & Research

1978 1981 University of Ottawa, Canada Chair, Dept. of Electrical Engineering

1975 1980 University of Ottawa, Canada Assoc. Prof., Teach. & Research

1969 1975 University of Ottawa, Canada Assist. Prof., Teach. & Research

1968 1969 Université de Grenoble, France Postdoctoral Fellow, Research

1968 1969 IUT de Grenoble, France Lecturer, Teach. of Courses & Labs

Visiting Appointments

2007 (Aug) ‘07(Nov) ETH Zürich, Switzerland Visiting Professor, Research

2007 (Apr) ’07 (Jul) TU München, Germany Visiting Professor, Res. & Teach.

2005 (Apr) ’05 (Jun) University of Perugia, Italy Visiting Professor, Research

2005 (Mar) ’05 (Apr) GeorgiaTech, Atlanta GA, USA Visiting Professor, Research

1999 (Oct) ’99 (Dec) TU München, Germany Visiting Professor, Res. & Teach.

1996 (Apr) ’96 (May) University of Duisburg, Germany Visiting Professor, Research

1991 (Apr) ’91 (Jun) TU München, Germany Visiting Professor, Res. & Teach.

1990 (Oct) ’91 (Mar) U. Nice-Sofia Antipolis, France Visiting Professor, Research

1990 (Jul) ’90 (Sep) U. Of Rome Tor Vergata, Italy Visiting Professor, Research

1984 (Jul) ’85 (Sep) Comm. Res. Centre, Ottawa, CDN Visiting Scientist, Research

1977 (Jan) ’77 (Jul) Inst. Natl. Polyt. Grenoble, France Visiting Professor, Research

1976 (Jun) ’76 (Dec) AEG Telefunken Backnang, Germ. Visiting Scientist, Research

Appendix 2 – page 3 6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

Life Fellow, IEEE (2006) Fellow, Canadian Academy of Engineering (2009) Fellow, Royal Society of Canada (2003) Fellow, German Academy of Science and Engineering - ACATECH (2007) Fellow, Advanced Systems Institute of British Columbia (1992) Fellow, IEEE (1991) McNaughton Gold Medal (IEEE Canada, 2009) Honorary Doctorate in Electrical Engineering, Technische Universität München, Germany (2007) Distinguished Educator Award, IEEE MTT-Society (2006) Distinguished Microwave Lecturer, IEEE MTT-Society (2003-2005) Mainstay Award, Advanced Computational Electromagnetics Society (2004) Peter B. Johns Prize (John Wiley & Sons), 1989 URSI, Commission B (1987) IEEE-MTT, -AP and –EMC Societies (since 1971) Chair of IEEE-MTT-15 Technical Committee on Field Theory (1995 – 2002) Co-Chair of IEEE-MTT-15 Technical Committee on Field Theory (1989 – ’95 & 2002 – ‘04) Editor-in-Chief, International Journal of Numerical Modelling (1989 – 2009) Associate Editor (Electromagnetics/Guided Waves), IEEE MTT-Transactions (1998 – 2000) Scientific Advisory Board, Ferdinand Braun Institute, Berlin, Germany (1993 – 1998) Board of Directors, Vancouver Island Advanced Technology Center (VIATEC) (1997 – 1999)

7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex – maximum 5 pages)

- Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions...... Attached

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT

X Balthasar van der Pol Gold Medal

John Howard Dellinger Gold Medal

Appleton Prize

Booker Gold Medal

Issac Koga Gold Medal

Appendix 2 – page 4 9. ARGUMENTS IN SUPPORT OF THE NOMINATION (Limit to this page)

I nominate Professor Hoefer by virtue of his pioneering work in electromagnetic field theory and its applications in microwave, millimetre-wave and optical engineering. During the early years of his career he became known for his work on the interaction of electromagnetic waves with resonant ferrites, which culminated in a method for measuring the Q-factor of YIG spheres of extremely narrow linewidth (< 0.3 Oe). Subsequently, he developed analytical expressions for the wave properties of quasi-planar waveguides and their discontinuities through rigorous field analysis. These expressions laid the foundation of computer-aided design of E-plane circuits for extremely wide- band millimetre-wave components. Touchstone and Super-Compact, the first microwave design tools and precursors of today’s powerful simulators, featured several of his models. The engineering relevance of his scientific research led to numerous collaborative projects with industry and had a significant impact on the evolution of information technology during the late 1970s.

When personal computers with rapidly growing memory and speed entered the mainstream of scientific and engineering research in the 1980s, Professor Hoefer was among the first to perceive the parallel nature and the extraordinary promise of explicit time-domain methods for solving grand- challenge electromagnetic field problems. At a time when most practitioners rejected such methods as unsuitable and impractical, he convincingly demonstrated that time domain methods, notably the Finite Difference Time Domain (FDTD) and Transmission Line Matrix (TLM) methods, could indeed solve complex, dispersive, non-linear, transient and anisotropic field problems with accuracy and speed. His seminal papers on the Theory and Practice of the TLM Method, published in 1985, and on the use of FDTD for solving eigenvalue problems in 1986, arguably heralded the emergence of the TLM and FDTD methods as major modelling paradigms in computational electromagnetics. The TLM paper has been cited 293 times (with 10 citations in 2010), and the FDTD paper received 128 citations. Throughout the past 25 years, Professor Hoefer has spearheaded, and continues to lead, the evolution of these methods from promising algorithms to sophisticated software tools. Microwave and high-speed electronics, electromagnetic compatibility, signal integrity, superresolution imaging, metamaterial and plasmonics research are now unthinkable without these tools. Professor Hoefer’s principal contributions are documented in the attached selection of annotated publications. By translating his insights into a commercial software tool (MEFiSTo) he has put specialized knowledge and expertise into the hands of students, researchers and design engineers. As a dedicated educator he has launched the careers of many gifted scientists and engineers who are making their own mark in academia, research and industry. He continues to explore new frontiers in electromagnetics, devoting his career to scholarship, education, technology transfer and professional engagement. It is with enthusiasm and conviction that I nominate Professor Hoefer as an outstanding and highly deserving candidate for the Balthasar van der Pol medal.

Appendix: SELECTED PUBLICATIONS OF PROFESSOR HOEFER (The ten most significant titles are No. 1, 2, 4, 21, 22, 23, 29, 45, 47, and 58. They are marked with an asterisk *)

BOOKS:

1. * Hoefer, W.J.R. and P.P.M. So, “The Electromagnetic Wave Simulator, A Visual Electromagnetics Laboratory based on the 2D TLM Method”, John Wiley & Sons, Chichester, UK., 1991, 150 pages. This book on the theory of the two-dimensional TLM method included a floppy diskette containing the first commercial interactive TLM electromagnetic wave simulator for PC, as well as a Visual Electromagnetics Laboratory with extensive numerical experiments in microwave theory and techniques. 2. * Swanson, D.G. Jr. and W.J.R. Hoefer, “Microwave Circuit Modeling Using Electromagnetic Field Simulation" Artech House Publishers, Boston, MA, 2003, 436 pages, ISBN 1-58053-308-6. This book is a theoretical and practical introduction to electromagnetic field solvers. It provides professionals with helpful advice on selecting the suitable tool for a given type of problem, and stresses the impact of meshing, geometrical resolution and convergence on the accuracy and speed of the principal time- and frequency-domain methods.

CHAPTERS IN BOOKS:

3. Hoefer, W.J.R. Microwave Amplifiers Chapter 4 of the book "Digital Communication: Microwave Applications" by K. Feher, Prentice-Hall, Inc., Englewood Cliffs, N.J., 1981, pp. 78-93 (15 pages). This book chapter summarizes the principles and characteristics of microwave amplifiers in the context of digital communications at microwave frequencies. 4. * Hoefer, W.J.R. The Transmission Line Matrix (TLM) Method, Chapter 8 of "Numerical Techniques for Passive Microwave and Millimeter-Wave Structures," edited by T. Itoh, John Wiley & Sons, New York 1989, pp. 496-591, (95 pages). This chapter contains a detailed treatise of the TLM method and its application to electromagnetic wave problems. The method has considerably evolved since the publication of this book, but this chapter has been instrumental in making the TLM method widely known and accepted in the electromagnetics and microwave communities. 5. Hoefer, W.J.R., “Modeling and design of millimeter-wave components in the time domain with TLM techniques” in Volume CR54 “Critical Reviews of Optical Science and Technology”, edited by James C. Wiltse, SPIE Press, Bellingham, WA, 1994, pp. 166-188, (23 pages). This contribution is aimed at the optical community. It describes the advantages of designing millimetre-wave components in the time domain using TLM modelling. 6. Vahldieck, R. and W.J.R. Hoefer, “Electromagnetic Modeling” in Vol. 6 of “Wiley Encyclopedia of Electrical and Electronics Engineering”, edited by John G. Webster, John Wiley & Sons, New York, 1999. 7. Hoefer. W.J.R. and R. Vahldieck, “Finlines”, in Vol. 7 of “Wiley Encyclopedia of Electrical and Electronics Engineering”, edited by John G. Webster, John Wiley & Sons, New York, 1999, pp. 545- 555, (10 pages) These two invited chapters in the Wiley Encyclopedia of Electrical and Electronics Engineering summarize the state of the art in computational electromagnetics, and the analysis and design of Finlines for wide-band millimetre-wave applications, respectively. 8. Hoefer. W.J.R., “Transmission Line Matrix (TLM) Modeling Method” and “Negative Refractive Index (NRI) Effects”, Sections 4.3 and 4.4, of the book “Electromagnetic Metamaterials” by C. Caloz and T. Itoh, John Wiley & Sons, Hoboken, NJ, 2006, pp. 158-170, (12 pages). The modelling of negative refractive index metamaterials with the TLM method is described in these two sections, and the major unusual effects, such as negative phase velocity, negative refraction and superresolution imaging with the Veselago-Pendry lens, are visualized.

PUBLICATIONS IN REFEREED JOURNALS:

Interaction between electromagnetic fields and resonant ferrites: The following three publications describe the interaction between electromagnetic fields and highly-resonant ferrites. The application of the novel coupling theory to the measurement of very narrow linewidths of less than 0.3 Oe is discussed. 9. Bouthinon, M., W.J.R. Hoefer and Makram (Submitted to the Académie des Sciences by Louis Néel). "Couplage d'une cavité électromagnétique avec un échantillon de grenat à raie très étroite", C.R. Acad. Sc. Paris, t. 265, pp. 1081-1084, 13 Nov. 1967. 10. Hoefer, W.J.R., M. Bouthinon and A. Coumes. "Die Impedanz eines Hohlraumresonators mit einer gyromagnetischen Probe von sehr geringer Linienbreite", Nachrichtentechnische Zeitschrift (NTZ), vol. 23, no. 3, pp. 121-125, Mar. 1970. 11. Hoefer, W.J.R. "Power-frequency distribution in a cavity containing a resonant ferrite sample", Electronics Letters, vol. 9, no. 16, pp. 357-359, 9 Aug. 1973.

Experimental and theoretical characterization of microstrip discontinuities: The following publications describe experimental procedures for determining the equivalent circuits of microstrip discontinuities and coupling elements, and for validating discontinuity models derived through rigorous field analysis. Several of these models were incorporated in Touchstone and Super-Compact, the first commercial microwave design tools. 12. Hoefer, W.J.R. and A. Chattopadhyay, "Evaluation of the equivalent circuit parameters of microstrip discontinuities through perturbation of a resonant ring", IEEE Transactions on Microwave Theory and Techniques, vol. MTT-23, no. 12, pp. 1067-1071, Dec. 1975. 13. James, D.S., G.R. Painchaud and W.J.R. Hoefer. "Aperture coupling between microstrip and resonant cavities", IEEE-Trans. on Microwave Theory and Techniques, vol. MTT-25, no. 5, pp. 392- 398, May 1977. 14. Hoefer, W.J.R. "Fine tuning of microwave integrated circuits through longitudinal and transverse slits of variable length", NTZ Communications Journal, vol. 30, no. 5, pp. 421-424, May 1977. 15. Hoefer, W.J.R. "Equivalent series inductivity of a narrow transverse slit in microstrip", IEEE Trans. on Microwave Theory and Techniques, vol. MTT-25, no. 10, pp. 822-824, October 1977.

Quasi-Planar and E-Plane transmission media: The following five publications deal with the characterization of quasi-planar circuits and E-plane circuits (finlines) using various numerical techniques, among them the time domain TLM method. 16. Shih, Y-C. and W.J.R. Hoefer. "The accuracy of TLM-analysis of finned rectangular waveguides", IEEE Trans. on Microwave Theory and Techniques, vol. MTT-28, no. 7, pp. 743-746, July 1980. 17. Sharma, A.K. and W.R.J. Hoefer. "Spectral domain analysis of a hexagonal microstrip resonator", IEEE Trans. on Microwave Theory and Techniques, vol. MTT-30, no.5, pp. 825-828, May 1982. 18. Hoefer, W.J.R. and M.N. Burton. "Closed-form expressions for the parameters of finned and ridged waveguides", IEEE Trans. on Microwave Theory and Techniques, vol. MTT-30, no. 12, pp. 2190- 2194, Dec. 1982. 19. Sharma, A.K. and W.J.R. Hoefer. "Propagation in coupled unilateral and bilateral finlines", IEEE Transactions on Microwave Theory and Techniques, vol. MTT-31, no. 6, pp. 498-502, June 1983. 20. El-Ghazaly, S. and W.J.R. Hoefer. "Effect of number of spectral terms on convergence of spectral domain calculations of E-Plane structures", Electron. Lett., vol. 21, no. 16, pp. 677-678, Aug. 1, 1985.

Seminal papers on TLM and FDTD: These are the most frequently and consistently cited publications by Professor Hoefer, heralding the emergence of the TLM and FDTD methods as major modelling paradigms in computational electromagnetics. These papers have significantly contributed to the acceptance of time domain modelling by the microwave community which has traditionally relied on complex frequency domain solutions of Maxwell’s equations, and initially considered the time domain approach as unsuitable and impractical. For the third paper, Professor Hoefer received the Peter B. Johns Prize in 1989.

21. * Hoefer, W.J.R. "The transmission line matrix method - theory and applications", Invited Paper, Special issue on numerical methods, IEEE Trans. on Microwave Theory and Techniques, vol. MTT- 33, no.10, pp. 882-893, Oct. 1985. 22. * Choi, D. and W.J.R. Hoefer. "The finite difference - time domain method and its applications to eigenvalue problems", IEEE Trans. on Microwave Theory and Techniques, vol. MTT-34, no. 12, pp. 1364-1470, Dec. 1986. 23. * Hoefer, W.J.R. "The discrete time domain Green's function or Johns matrix - A new powerful concept in TLM", Invited Paper, Intl. Journal of Numerical Modelling, vol. 2, no. 4, pp. 215-225, Dec. 1989.

E-Plane filters and Components: The following papers describe realizations of major significance for industrial applications. Using highly accurate numerical techniques and circuit models based on rigorous field analysis, it now became possible to reliably design components that no longer required trimming or tuning.

24. Vahldieck, R. and W.J.R. Hoefer, "Finline and metal insert filters with improved pass-band separation and increased stopband attenuation", IEEE Trans. on Microwave Theory and Techniques, vol. MTT-33, no. 12, pp. 1333-1339, Dec. 1985. 25. Vahldieck, R. and W.J.R. Hoefer, "Rigorous analysis of novel dielectric resonator filters with printed tuning septum", Intl. Journal of Infrared and Millimeter Waves, vol. 8, no. 7, pp. 711-721, July 1987. 26. Hoefer, W.J.R. "Oscillators and amplifiers in integrated E-plane technique", Invited Paper, IEEE Trans. Microwave Theory Techniques, Special Issue on Quasi-Planar Circuits, vol. MTT-37, no. 2, pp. 351-364, Feb. 1989. 27. Callsen, H., H. Meinel and W.J.R. Hoefer. "PIN diode control devices in E-plane technique", Invited Paper, IEEE Trans. Microwave Theory Techniques, Special Issue on Quasi-Planar Circuits, vol. MTT-37, no. 2, pp. 309-316, Feb. 1989. 28. L'Ecuyer, J., G. Gajda and W.J.R. Hoefer. "A FET amplifier in finline technique", IEEE Trans. Microwave Theory Techniques, Special Issue on Quasi-Planar Circuits, vol. MTT-37, no. 2, pp. 425-428, Feb. 1989. 29. * Uher, J. and W.J.R. Hoefer. "Tunable microwave and mm-wave bandpass filters", IEEE Trans. Microwave Theory Techniques, vol. MTT-39, no. 4, pp. 643-653, April 1991.

Seminal contributions to the development of the TLM Method: The following papers highlight major contributions by Professor Hoefer and his research associates to TLM modelling of electromagnetic waves.

30. Hoefer, W.J.R. "Linear and nonlinear modelling in the time domain with the transmission line matrix (TLM) method", Invited Paper, Alta Frequenza, vol. LVIII, no. 5-6, ,pp. 541-549 (105-113), October 1989. 31. Russer, P., P.P.M. So and W.J.R. Hoefer, "Modeling of nonlinear active regions in TLM", IEEE Microwave and Guided Wave Letters, vol. 1, no. 1, pp. 10-13, Jan. 1991.

32. Nielsen, J.S. and W.J.R. Hoefer, "A Complete Dispersion Analysis of the Condensed Node TLM Mesh", IEEE Trans. on Magnetics, vol. 27, no. 5, pp. 3982-3985, Sep. 1991. 33. Hoefer, W.J.R., "Huygens and the computer - A powerful alliance in numerical electromagnetics", Proc. IEEE, Special Issue on Electromagnetics, vol. 79, no. 11, pp. 1459-1471, October 1991. 34. Müller, U., Beyer, A., and Hoefer, W.J.R., "Moving Boundaries in 2D and 3D TLM Simulations Realized by Recursive Formulas", IEEE Trans. Microwave Theory Techniques, vol. MTT-40, no. 12, pp. 2267-2271, Dec. 1992. 35. Nielsen, J.S., Hoefer, W.J.R., "Modelling of Nonlinear Elements in a 3D Condensed Node TLM Mesh", International Journal of Microwave and Millimeter-Wave Computer-Aided Engineering, vol. 3, no. 1, pp. 61-66, Jan. 1993. 36. Zhang, Q., Hoefer, W.J.R., "Characteristics of New 3D Distributed Node TLM Mesh with Cells of Arbitrary Aspect Ratio", IEEE Trans. Microwave Theory Techniques, pp. 369-371, Dec. 1994. 37. Righi, M., Hoefer, W.J.R., "Efficient 3D-SCN-TLM Diakoptics for Waveguide Components", IEEE Trans. Microwave Theory Techniques, vol. MTT-42, no. 12, pp. 2381-2385, Dec. 1994. 38. Forest, M., and Hoefer, W.J.R.,"A Novel Synthesis Technique for Conducting Scatterers using TLM Time Reversal," IEEE Trans. Microwave Theory Techniques, vol. MTT-43, no. 6, pp. 1371-1378, June 1995. 39. de Menezes, L.R.A.X. and Hoefer, W.J.R., "Modeling of General Constitutive Relationships in SCN TLM", IEEE Trans. Microwave Theory and Techniques. vol. MTT-44, no. 6, pp. 854-861, June 1996. 40. Eswarappa, C. and Hoefer, W.J.R., "Absorbing Boundary Conditions for Time Domain TLM and FDTD Analysis of Electromagnetic Structures", Electromagnetics, vol. 16, no. 5, pp. 489-519, Sept./Oct. 1996. 41. Righi, M., Herring, J.L., and Hoefer, W.J.R., “Efficient Hybrid TLM/Mode-Matching Analysis of Packaged Components", IEEE Trans. Microwave Theory and Techniques. vol. MTT-45, no. 10, pp. 1715-1724, Oct. 1997. 42. Bakr, M, So, P.P.M., and Hoefer, W.J.R. “The Generation of Optimal Microwave Topologies Using Time Domain Field Synthesis” IEEE Trans. Microwave Theory and Techniques, vol. MTT-50, no. 11, pp. 2537-2544, Nov. 2002. 43. So, P.P.M. and Hoefer, W.J.R., “A TLM-SPICE Interconnection Framework for Coupled Field and Circuit Analysis in the Time Domain”, IEEE Trans. Microwave Theory and Techniques. vol. MTT- 50, no. 12, pp. 2728-2733, Dec 2002. 44. Sallier, A., J. Bornemann and W. J. R. Hoefer, “Field-Based Waveguide Filter Synthesis in the Time Domain”, Invited Paper, AEÜ International Journal of Electronics and Communications, vol. 57, no. 2, pp. 119-127, May 2003. 45. * So, P. P. M., H. Du and W. J. R. Hoefer “Modeling of metamaterials with negative refractive index using 2D-shunt and 3D-SCN TLM networks” IEEE Trans. Microwave Theory Tech., Special Issue on Metamaterials, vol. MTT-53, no. 4, pp. 1496- 1505, Apr. 2005. 46. Hoefer, W. J. R., H. Du and P. P. M. So “Wave properties of computational TLM models of metamaterials with negative refractive index” Intl. Journal of Numerical Modelling, Focussed Issue on Numerical Modelling of Metamaterial Properties, Structures and Devices, vol. 19, no. 2, pp. 119- 139, Mar./Apr. 2006.

Seminal contributions to the development of the Finite Difference Time Domain (FDTD) and Multiresolution Time Domain (MRTD) Methods: The following papers highlight major contributions by Professor Hoefer and his research associates to FDTD and MRTD modelling of electromagnetic waves.

47. * Kim, I.S. and W.J.R. Hoefer. "A local mesh refinement algorithm for the time domain - finite difference method using Maxwell's curl equations", IEEE Trans. Microwave Theory Techniques, vol. MTT-38, no. 6, pp. 812-815, June 1990. 48. Kim, I.S. and W.J.R Hoefer. "Numerical dispersion characteristics and stability factor for the FD-TD method", Electron. Lett., vol. 26, no. 7, pp. 485-487, March, 29, 1990. 49. Chen, Z., M.M. Ney and W.J.R. Hoefer. "A new finite-difference time-domain formulation and its equivalence with the TLM symmetrical condensed node", IEEE Trans. Microwave Theory Techniques, vol. MTT-39, no. 12, pp. 2160-2169, Dec. 1991. 50. Eswarappa, C. and Hoefer, W.J.R., "Bridging the Gap between TLM and FDTD", IEEE Microwave and Guided Wave Letters, vol. 6, no. 1, pp. 4-6, January 1996. 51. Fujii, M. and Hoefer, W.J.R., “A 3D Haar-Wavelet-Based Multiresolution Analysis Similar to the FDTD Method - Derivation and Application” IEEE Trans. Microwave Theory and Techniques. vol. MTT-46, no. 12, pp. 2463-2475, Dec. 1998. 52. Fujii, M. and Hoefer, W.J.R., “Dispersion of Time Domain Wavelet-Galerkin Method based on Daubechies' Compactly Supported Scaling Functions with Three and Four Vanishing Moments”, IEEE Microwave and Guided Wave Letters, vol. 10, no. 4, pp. 125-127, Apr. 2000. 53. Fujii, M. and Hoefer, W.J.R., “Field Singularity Correction in 2-D Time Domain Haar Wavelet Modeling of Waveguide Components”, IEEE Trans. Microwave Theory and Techniques. vol. MTT- 49, no. 4, pp. 685-691, April 2001. 54. Fujii, M. and Hoefer, W.J.R., “A Wavelet Formulation of Finite Difference Method: Full Vector Analysis of Optical Waveguide Junctions”, IEEE Journal of Quantum Electronics, vol. 37, no. 8, pp. 1015-1029, August 2001. 55. Barba, I., Represa, J., Fujii, M. and Hoefer, W.J.R., “Multiresolution Model of Electromagnetic Wave Propagation in Dispersive Materials”, International Journal of Numerical Modelling, vol. 16, no. 3, pp. 239-247, May/Jun 2003. 56. Fujii, M. and W. J. R. Hoefer, “Interpolating wavelet collocation method of time dependent Maxwell’s equations: characterization of electrically large optical waveguide discontinuities”, Journal of Computational Physics, vol. 186, pp. 666-689, 2003. 57. Grande, A., I. Barba, A. C. L. Cabeceira, J. Represa, P. P. M. So, and W. J. R. Hoefer, “FDTD modeling of transient microwave signals in dispersive and lossy bi-isotropic media” IEEE Trans. Microwave Theory Tech., vol. MTT-52, no. 3, pp. 773 - 784, Mar. 2004. Other recent contributions related to computational electromagnetics: 58. * Du, H. D. Gorcea, P. P. M. So, and W. J. R. Hoefer, “A SPICE analog behavioral model of two- port devices with arbitrary port impedances based on the S-parameters extracted from time-domain field responses” Intl. Journal of Numerical Modelling, Focussed Issue on the 2006 FACE Workshop in Victoria, vol. 21, no. 1-2, pp. 77-90, Jan./Feb. 2008. 59. Wang, H., P. So, S. Yang, W. J. R Hoefer, H. Du, “Numerical Modeling of Multicomponent Induction Well-Logging Tools in the Cylindrically Stratified Anisotropic Media”, IEEE Trans. Geoscience and Remote Sensing, vol. 46, no. 4, part 2, pp. 1134 – 1147, Apr 2008. 60. Hoefer, W. J. R., “On the Relationship between Discrete Algorithms in Computational Electro- magnetics” Frequenz, vol. 62, no. 7-8, pp. 205 – 207, Jul/Aug 2008.

Appendix 2 – page 1

INTERNATIONAL UNION OF RADIO SCIENCE

1. NAME OF CANDIDATE: HOTATE, Kazuo Last, First, Middle

PRESENT OCCUPATION: The University of Tokyo Position, Organization

Professor, Department of Electrical Engineering and Information Systems Graduate School of Engineering, the University of Tokyo

BUSINESS ADDRESS:

7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8656, JAPAN

HOME ADDRESS:

6-17-17 Fuda, Chofu-shi, Tokyo 182-0024, JAPAN

BIRTHDATE: June 20, 1951, NATIONALITY: Japanese, SEX: male - female (Underline the appropriate)

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year The University of Tokyo Tokyo, Japan Bachelor of Eng. 1974 Department of Electronic Engineering, Faculty of Engineering The University of Tokyo Tokyo, Japan Master of Eng. 1976 Department of Electronic Engineering, Graduate School of Engineering The University of Tokyo Tokyo, Japan Doctor of Eng. 1979 Department of Electronic Engineering, Graduate School of Engineering

3. PROPOSED CITATION (not more than thirty words) For contribution to optical fibre sensing with particular reference to functional fibre optic nerve systems realized by synthesis of coherence function of continuous lightwave

4. NOMINATOR: Prof. Motoichi Ohtsu ADDRESS: Department of Electrical Engineering and Information Systems Graduate School of Engineering, the University of Tokyo 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8656, JAPAN PHONE: +81-3-5841-1189 FAX: +81-3-5841-1140 E-MAIL : [email protected]

Appendix 2 – page 2 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

From (year) to (year) Name of Company/Institution Position and Responsibilities

2001 present The University of Tokyo Professor

Faculty and Graduate School of Engineering

2007 present The University of Tokyo Leader

Global Centre of Excellent Program on EE launched by MEXT

2008 2010 The University of Tokyo Dean

Faculty and Graduate School of Engineering

2006 2008 The University of Tokyo Vice Dean

Faculty and Graduate School of Engineering

2002 2006 The University of Tokyo Leader

21th Century COE Program on EE launched by MEXT

1999 2001 The University of Tokyo Professor

Graduate School of Frontier Sciences

1997 1999 The University of Tokyo Professor

Faculty and Graduate School of Engineering

1993 1997 The University of Tokyo Professor

Research Centre for Advanced Science and Technology

1987 1993 The University of Tokyo Associate Professor

Research Centre for Advanced Science and Technology

1981 1987 The University of Tokyo Lecture

Faculty and Graduate School of Engineering

1979 1981 The University of Tokyo Lecture

Institute of Space and Aeronautical Science

Appendix 2 – page 3 6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

1. Achievement Award, Institute of Electronics, Information and Communication Engineers (IEICE), 1979. 2. Book Award, Institute of Electronics, Information and Communication Engineers (IEICE), 1984. 3. Paper Award, Society of Instrumentation and Control Engineers (SICE), 1984. 4. Best Paper Award, 4th Optoelectronics Conference (OEC), 1992. 5. Highest Scored Paper, 13th International Conference on Optical Fibre Sensors (OFS-13), 1999. 6. Highest Scored Paper, 14th International Conference on Optical Fibre Sensors (OFS-14), 2000. 7. Ichimura Prize, New Technology Development Foundation, 2001. 8. Hasunuma Prize, Society of Instrumentation and Control Engineers (SICE), 2002. 9. Electronics Society Award, Institute of Electronics, Information and Commun. Engineers (IEICE), 2003. 10. JJAP Paper Award, Japan Society of Applied Physics (JSAP), 2006. 11. Highest Scored Paper, 18th International Conference on Optical Fibre Sensors (OFS-18), 2006. 12. DDS Lifetime Achievement Award, SPIE; the International Society for Photonics, 2009. 13. Fellow, Society of Instrumentation and Control Engineers (SICE), 2000. 14. Fellow, Institute of Electrical and Electronic Engineers (IEEE), 2003. 15. Fellow, Institute of Electronics, Information and Communication Engineers (IEICE), 2004. 16. Fellow, Japan Society of Applied Physics (JSAP), 2008. 17. Executive Director, Member in Board of Directors, SICE, 1997-1998. 18. Executive Director, Member in Board of Directors, JSAP, 2003-2004. 19. Executive Director, Member in Board of Directors, IEICE, 2005-2006. 20. President, IEICE Electronics Society, 2006. 21. Chair, Japan Chapter of IEEE/Laser and Electro-optics Society, 2004. 22. Elected Member in Board of Governors, IEEE Laser and Electro-optics Society, 2007-2009. 23. Associate Editor, Journal of Lightwave Technology, IEEE/OSA, 2006-2008. 24. General Co-chair, SPIE Fibre Optic Gyros, 20th Anniversary Conference, 1996. 25. Technical Program Chair, 13th International Conference on Optical Fibre Sensors (OFS-13), 1999. 26. General Chair, 16th International Conference on Optical Fibre Sensors (OFS-16), 2003. 27. Member in International Steering Committee of OFS, 1999-2003.

7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex – maximum 5 pages)

- Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions.

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT

Balthasar van der Pol Gold Medal

John Howard Dellinger Gold Medal

Appleton Prize

Booker Gold Medal

Issac Koga Gold Medal

Appendix 2 – page 4 9. ARGUMENTS IN SUPPORT OF THE NOMINATION (Limit to this page) I would like to recommend Prof. Kazuo Hotate, the University of Tokyo, as a candidate for the Balthasar van der Pol Gold Medal. Since I had an honour to receive the Issac Koga Gold Medal from URSI in 1984, taking much interest in activities and programs of URSI, I have been working in my own field of nanophotonics. Then, among researchers working in related fields all over the world, I have realized Prof. Hotate should be a candidate for this Gold Medal. Prof. Hotate has accumulated his original works, for about 30 years, in research and development of “Optical Fibre Sensing,” especially on “Fibre Optic Gyros” since its early research stage, and especially on “Functional Fibre Optic Nerve Systems” (Distributed Fibre Optic Sensors) recently. He has proposed his own principles and systems for functional distributed fibre optic sensing, for example, for strain distribution, with quite high performances. His sensing principle is to synthesize arbitrarily coherence function of continuous lightwave. The realized high performances have not been obtained by any other principles. Health monitoring function for society key structures, such as bridges, highways and airplanes, to be realized by the “Functional Fibre Optic Nerve Systems” with his principles should be key technologies for the 21st century society, which seeks sustainability, earth environmental protection, and energy saving. He started lightwave related researches, as his diploma work, in a group of Profs. Sogo Okamura and Takanori Okoshi in the University of Tokyo. In the Graduate School, he contributed to the research on fibre characterization, which was selected as the Achievement Award form IEICE, and co-authored book on fibres (“Optical Fibres” in Japanese, Ohm-Sha, T. Okoshi, K. Okamoto and K. Hotate) received the Book Award also from IEICE. His successive and leading contribution to research and development of “Fibre Optic Gyros” (FOG) has been highly evaluated world widely. He demonstrated the “first FOG in Japan,” and proposed his own scheme to realize a wide dynamic range, which was selected as the Paper Award from SICE. His research to characterize the drift due to earth- magnetism through the Faraday-effect has also been highly evaluated. His invention on cost-effective FOG configurations has been productized by Japanese and U.S. gyro makers. He has also accumulated researches on next generation FOGs, on which he had the Highest Scored Paper in OFS-13. FOG has already been used in various applications, such as camera stabilizers, control for space satellites. Then, he also received the Ichimura Prize. Recently, he has proposed and developed unique “Functional Fibre Optic Nerve Systems.” Time domain techniques, based on pulsed lightwave with time resolved back scattering measurement, have traditionally been used. However, these had limitations in spatial resolution around 1m, and took longer measurement time around several minutes. On the contrary, in his schemes named “Synthesis of optical coherence function: SOCF,” which was selected as the Best Paper Award in OEC conference, he uniquely uses a continuous lightwave. By modulating a laser frequency with specific waveforms, he has realized arbitrary synthesis of interference characteristic of the continuous lightwave. He has developed various distributed sensing systems, for example, for monitoring Fibre to the Home networks with cm resolution, and for multiplexing fibre Bragg grating strain sensors having the same Bragg wavelength. He has recently proposed another bright technique, named “Brillouin Optical Correlation Domain Analysis; BOCDA.” By the SOCF, he realized position selective excitation of stimulated Brillouin scattering along an optical fibre. Even using continuous lightwave, a Brillouin spectrum at one position along an optical fibre can selectively be obtained. The position can easily be swept by changing the SOCF parameter. Through dependence of the Brillouin frequency shift on applied strain, its distribution along the fibre can be obtained. Resolution of 1.6 mm, measurement speed of 1kHz for one point, and random access ability have been realized. Though the time domain technologies have been improved recently, such BOCDA performances are still highest among various distributed schemes. Recently, Prof. Hotate has also proposed a scheme for simultaneous and discriminative measurement of strain and temperature. In his laboratory, it was shown that the acoustic wave grating, accompanied by the stimulated Brillouin scattering, can also make the Bragg reflection for the orthogonal polarization lightwave. This grating is named “Brillouin Dynamic Grating: BDG.” By using both the Brilluoin frequency shift and the BDG Bragg reflection, the discriminative measurement with 10 cm spatial resolution has recently been demonstrated by the BOCDA scheme. This is a great invention for accelerating practical applications of the “Fibre Optic Nerve Systems.” He has also proposed recently various types of other original nerve systems, for example, that using spontaneous (not stimulated) Brillouin scattering. His schemes have had much attention from various application fields, such as civil engineering, rail way systems, and aircraft technology. For example, health monitoring of a business jet aircraft was successfully demonstrated in flight condition, in 2007, applying the BOCDA prototype equipment, with his group and a Japanese aircraft maker. Prof. Hotate presented an Invited Talk, at the URSI General Assembly in 1999, in Toronto, on the early stage of his “Functional Fibre Optic Nerve Systems.” For recent 6 years, he has presented 48 journal papers, and 24 invited talks in international conferences, as shown in the Annex. He received a number of awards on the topic, such as the Highest Scored Paper in OFS-14 and OFS-18, the Hasumuma Prize form SICE, the Electronics Society Award from IEICE, the JJAP Paper Award from JSAP, and the DDS Lifetime Achievement Award from SPIE. He has been also selected as the Fellow from SICE, IEICE, JSAP, and IEEE for the contribution to the lightwave sensing. On the subjects, he has also obtained the large scale research grants form MEXT and the several Patents, as also shown in the Annex. He served as the TPC Chair for OFS-13, General Chair for OFS-16, and the General Chair for Fibre Optic Gyros; 20th Anniversary Conference. He was elected as the Executive Director in the Board of Directors of SICE, JSAP, IEICE, and IEEE/LEOS, and the President of the IEICE Electronics Society. He was also elected as Dean of the Faculty/Graduate School of Engineering, through which he has also much contributed to engineering education. Prof. Kazuo Hotate has earned an international reputation as a leading lightwave scientist based on his outstanding achievements in “Optical Fibre Sensing,” especially in his unique “Functional Fibre Optic Nerve Systems,” which he has recently proposed and developed. I believe his work meets well the present and future direction of URSI. Based on what I know of him and his excellent works, I have no doubt that he deserves the Balthasar van der Pol Gold Medal. Principal Publications and Paptents by Prof. Kazuo Hotate (from Aug. 2004 to Aug. 2010)

A. International Jounal Publications (A1-A48, form Aug. 2004 to Aug. 2010) (Under lined papers: ten most significant contributions)

A1 M. Kashiwagi and K. Hotate: “Elongation of measurement range by successively shifting measurement window in a high spatial resolution reflectometry for optical subscriber networks by synthesis of optical coherence function,” Measurement Science and Technol., Vo.15, No.8, pp. 1512-1518, Aug. 2004. A2 Z. He, S. Yoshiyama , M, Enyama and K. Hotate: “High-reflectance-resolution optical reflecto- metry with synthesis of optical coherence function,” Japanese Journal of Applied Physics, Vol.44, No.3A, pp.L117 - L119, Jan. 2005. A3 X. Fan, Z. He and K. Hotate: “Novel distributed fiber-optic strain sensor by localizing dynamic grating in polarization maintaining erbium-doped fiber: proposal and theoretical analysis,” Japanese Journal of Applied Physics, Vol.44, No.2, pp.1101-1106, Feb. 2005. A4 M. Enyama, Z. He, and K. Hotate: “Expansion of spatial measurement range by use of vernier effect in multiplexed fibre Bragg grating strain sensor with synthesis of optical coherence function,” Measurement Science and Technology, Vol.16, No.4, pp.977-983, Apr. 2005. A5 K. Hotate and T. Yamauchi: “Fiber-optic distributed strain sensing system by Brillouin optical correlation domain analysis with a simple and accurate time-division pump-probe generation scheme,” Japanese Journal of Applied Physics, Vol.44, No.32, pp.L1030-L1033, July 2005. A6 X. Fan, Z. He, Y. Mizuno and K. Hotate: “Bandwidth-adjustable dynamic grating in Erbium-doped fiber by synthesis of optical coherence function,” OSA Optics Express, Vol.13, No.15, pp.5756-5761, July 2005. A7 X. Fan, Z. He, and K. Hotate: “Novel strain- and temperature-sensing mechanism based on dynamic grating in polarization-maintaining erbium-doped fiber,” OSA Optics Express Vol.14, No.2, pp.556-561, Jan. 2006. A8 K.-Y. Song and K. Hotate: “Enlargement of measurement range in a correlation-based Brillouin sensing system using double lock-in amplifiers and a single-sideband modulator,” IEEE Photonics Technology Letters, Vol.18, N0.3, pp.499-501, Feb. 2006. A9 Z. He, T. Tomizawa, and K. Hotate: “High-speed high-reflectance-resolution reflectometry by synthesis of optical coherence function,” IEICE Electronics Express, Vol.3, No.7, pp.122-128, Apr. 2006. A10 K.-Y. Song, Z. He and K. Hotate: “Optimization of Brillouin optical correlation domain analysis system based on intensity modulation scheme,” OSA Optics Express, Vol.14, No.10, pp.4256-4263, May 2006. A11 K.-Y. Song, K.-S. Abedin, K. Hotate, M.-G. Herráez and L. Thévenaz: “Highly efficient Burillouin slow and fast light using As2Se3 chalcogenide fiber,” OSA Optics Express, Vol.14, No.13, pp.5860-5865, June 2006. A12 K. Hotate and Z. He, “Synthesis of optical coherence function and its applications in distributed and multiplexed optical sensing,” IEEE J. of Lightwave Technology, Vol.24, No.7, pp.2541-2557, July 2006, . A13 K. Hotate, K. Makino, Z. He, M. Ishikawa and Y. Yoshikuni: “High spatial resolution fiber-optic distributed lateral-stress sensing by stepwise frequency modulation of a super structure grating distributed Bragg reflector laser diode,” IEEE J. of Lightwave Technology, Vol.24, No.7, pp.2733-2740, July 2006. A14 K.-Y. Song, Z. He and K. Hotate: “Distributed strain measurement with millimeter-order spatial resolution based on Brillouin optical correlation domain analysis,” OSA Optics Letters, Vol.31, No.17, pp.2526-2528, Sep. 2006. A15 W. Zou, Z. He and K. Hotate: “Two-dimensional finite-element modal analysis of Brillouin gain

- 1 - spectra in optical fibers, “IEEE Photonics Technology Letters, Vol.18, No.23, pp.2487-2489, Nov. 2006. A16 K. Hotate, “Fiber Sensor Technology Today,” Jpn. J. of Appl. Physics, special Issue for Microoptics, Vol.45, No.8B, pp.6616-6625, Dec. 2006. A17 K. Hotate, K. Abe and K.-Y. Song: “Suppression of signal fluctuation in Brillouin optical correlation domain analysis system using polarization diversity scheme,” IEEE Photonics Technology Letters, Vol.18, No.24, pp.2653-2655, Dec. 2006. A18 K.-Y. Song and K. Hotate: “25 GHz bandwidth Brillouin slow light in optical fibers,” Optics Letters, Vol.32, No.3, pp.217-219, Feb. 2007. A19 W. Zou, Z. He, M. Kishi and K. Hotate: “Stimulated Brillouin scattering and its dependences on strain and temperature in a high-delta optical fiber with F-doped depressed inner cladding,” Optics Letters, Vol.32, No.6, pp.600-602, Mar. 2007. A20 K.-Y. Song, Z. He and K. Hotate: “Effects of intensity modulation of light source on Brillouin optical correlation domain analysis,” J. of Lightwave Technology, Vol.25, No.5, pp.1238-1246, May 2007. A21 W. Zou, Z. He, A. D. Yablon and K. Hotate: “Dependence of Brillouin frequency shift in optical fibers on draw-induced residual elastic and inelastic strains,” IEEE Photonics Technology Letters, Vol.19, No.18, pp.1389-1391, Sept. 2007. A22 K.-Y. Song and K. Hotate: “Distributed fiber strain sensor at 1 kHz sampling rate based on Brillouin optical correlation domain analysis,” IEEE Photonics Technology Letters, Vol.19, No.23, pp.1928-1930, Dec. 2007. A23 K.-Y. Song, K.S. Abedin, and K. Hotate: “Gain-assisted superluminal propagation in tellurite glass fiber based on stimulated Brillouin scattering,” OSA Optics Express, Vol.16, No.1, pp.225-230, Jan. 2008. A24 K.-Y. Song, W. Zou, Z. He and K. Hotate: “All-optical dynamic grating generation based on Brillouin scattering in Polarization-maintaining fiber,” Optics Letters, Vol.33, No.9, pp.926-938, May 2008. A25 K. Hotate and K. Kajiwara: “Proposal and experimental verification of Bragg wavelength distribution measurement within a long-length FBG by synthesis of optical coherence function,” OSA Optics Express, Vol.16, Issue 11, pp. 7881-7887, June 2008. A26 W. Zou, Z. He and K. Hotate: “Acoustic modal analysis and control in w-shaped triple-layer optical fibers with highly-germanium-doped core and F-doped inner cladding,” OSA Optics Express, Vol.16, No.14, pp.10006-10017, June. 2008. A27 X. Fan, Z. He, and Kazuo Hotate: “Distributed strain sensor based on dynamic grating in polarization-maintaining erbium-doped fiber,” Opt. Lett., Vol.33, No.15, pp.1647-1649, Aug. 2008. A28 Y. Mizuno, W. Zou, Z. He and K. Hotate: “Proposal of Brillouin optical correlation-domain reflectometry (BOCDR),” OSA Optics Express, Vol.16, Issue 16, pp. 12148-12153, July 2008. A29 K. Hotate, H. Arai and K.-Y. Song: “Range-enlargement of simplified Brillouin optical correlation domain analysis based on a temporal gating scheme,” SICE J. of Control, Measurement, and System Integration, Vol.1, No.4, pp.271-274, July 2008 . A30 W. Zou, Z. He and K. Hotate: “Investigation of strain- and temperature- dependences of Brillouin frequency shifts in GeO2-doped optical fibers,” J. of Lightwave Technology, Vol.26, No.13, pp.1854-1861, July 2008. A31 K.-Y. Song and K. Hotate: “Brillouin optical correlation domain analysis in linear configuration,” IEEE Photonics Technology Letters, Vol.20, No.24, pp.2150-2152, Dec. 2008. A32 W. Zou, Z. He and K. Hotate: “Complete discrimination of strain and temperature using Brillouin frequency shift and birefringence in a polarization-maintaining fiber,” OSA Optics Express, Vol.17, No. 3, pp. 1248-1255, Jan. 2009. A33 Y. Mizuno, Z. He and K. Hotate: “One-end-access high-speed distributed strain measurement with 13-mm spatial resolution based on Brillouin optical correlation-domain reflectometry,” IEEE Photonics Technology Letters, Vol.21, No.7, pp.474-476, Apr. 2009.

- 2 - A34 Y. Mizuno, Z. He and K. Hotate: “Polarization beat length distribution measurement in single-mode optical fibers with Brillouin optical correlation-domain reflectometry,” Applied Physics Express, Vol.2, Paper no. 046502, Apr. 2009. A35 W. Zou, Z. He, K.Y.-Song and K. Hotate: “Correlation-based distributed measurement of dynamic grating spectrum generated in stimulated Brillouin scattering in a polarization-maintaining optical fiber,” OSA Optics Letters, Vol.34, No.7, pp1126-1128, April 2009. A36 M. Kashiwagi and K. Hotate: “Long range and high resolution reflectometry by synthesis of optical coherence function at region beyond the coherence length,” IEICE Electronics Express, Vol.6, No.8, pp.497-503, Apr. 2009. A37 K.-Y. Song, W. Zou, Z. He and K. Hotate: “Optical time-domain measurement of Brillouin dynamic grating spectrum in a polarization-maintaining fiber,” OSA Optics Letters, Vol.34, No.9, PP.1381-1383, May 2009. A38 Y. Mizuno, Z. He and K. Hotate: “Measurement range enlargement in Brillouin optical correlation-domain reflectometry based on temporal gating scheme,” OSA Optics Express, Vol. 17, No. 11, pp.9040-9046, May 2009. A39 Y. Mizuno, Z. He and K. Hotate: “Stable entire-length measurement of fiber strain distribution by Brillouin optical correlation-domain reflectometry with polarization scrambling and noise-floor compensation,” Applied Physics Express, Vol.2, Paper no. 062403, June 2009. A40 K. Kajiwara and K. Hotate: “Measurement of Bragg-wavelength distribution in a long-length fiber bragg grating with high speed sampling,” Applied Physics Express, Vol.2, No.8, Paper no. 082401, Aug. 2009. A41 Y. Jeong, K.-Y. Song, K. Hotate and K. Oh: “Analysis of Brillouin frequency shift and acoustic waves in a hollow optical fiber, OSA Optics Letters, Vol.34, No.20, pp.3217-3219, Oct. 2009. A42 Y. Mizuno, Z. He and K. Hotate: “Dependence of the Brillouin frequency shift on temperature in a tellurite glass fiber and a bismuth-oxide highly-nonlinear fiber,” Applied Physics Express, Vol. 2, No. 11, pp. 112402.1-3, Oct. 2009. A43 W. Zou, Z. He, and K. Hotate: “Tunable fiber-optic delay line based on stimulated Brillouin scattering,” Applied Physics Express, Vol. 3, No. 1, pp.12501.1-3, Jan. 2010. A44 X. Wang, Z. He and K. Hotate: “Reduction of polarization-fluctuation induced drift in resonator fiber optic gyro by a resonator with twin 90o polarization-axis rotated splices,” OSA Optics Express, Vol. 18, Issue 2, pp. 1677-1683, Jan. 2010. A45 Y. Mizuno, Z. He, and K. Hotate: “Measurement range enlargement in Brillouin optical correlation-domain reflectometry based on double-modulation scheme,” OSA Optics Express, Vol. 18, No. 6, pp. 5926-5931, Mar. 2010. A46 Y. Mizuno, Z. He, and K. Hotate: “Distributed strain measurement using a tellurite glass fiber with Brillouin optical correlation-domain reflectometry,” Optics Communications, No.238, pp.2439-2442, Apr. 2010. A47 W. Zou, Z. He, and K. Hotate: “Demonstration of Brillouin distributed discrimination of strain and temperature based on a polarization-maintaining optical fiber,” IEEE Photonics Technology Letters, Vol. 22, No. 8, pp. 526-528, Apr. 2010. A48 W. Zou, Z. He, and K. Hotate: “Single-end-access correlation-domain distributed fiber-optic sensor based on stimulated Brillouin scattering,” Jour. of Lightwave Technology, Vol.28, 2010, accepted.

B. Invited Papers in International Conferences (B0, B1-B24, from Aug. 2004 to Aug. 2010)

B0 K. Hotate: “Photonic sensing by use of synthesis of optical coherence function,” URSI GA’99, Toronto, p.26, Aug. 1999 . B1 K. Hotate: “Fiber optic nerve systems for smart materials and smart structures,” SPIE Optics East 2004, Philadelphia, 5604-1, pp.1-10, Oct. 26-28, 2004 < Invited>. B2 Z. He and K. Hotate: “Application of synthesized coherence function to distributed optical sensing,”

- 3 - SPIE APOC2004 Conference, Beijing, 5623-84, pp.554-568, Nov. 2004 < Invited>. B3 K. Hotate: “Fiber optic nerve systems with optical correlation domain technique for smart structures and smart materials,” North American Euro-Pacific Workshop on Sensing Issue in Civil Structual Health Monitoring, Hawaii, Nov. 10-13, 2004 < Invited>. B4 K. Hotate: “Correlation –based continuous-wave technique for optical fiber distributed strain measurement using Brillouin scattering,” 17th Intern. Conf. on Optical Fiber Sensors (OFS-17), Bruges, Tu-1, pp.62-67, May 23-27, 2005 < Invited>. B5 K. Hotate: “Materials that feel pain – distributed strain sensing by optical fibers embedded in structures and materials,” IEEE/LEOS International Conference on Optical MEMs and Their Applications, Oul, PLE2, pp.5-6, Aug. 1-5, 2005 . B6 K. Hotate: “Distributed and multiplexed fiber optic sensors and their applications to smart structures and smart materials,” the 2005 Optical Amplifiers a nd Their Applications Meeting, Budapest, TuA4, Aug. 7-11, 2005 . B7 Z. He and K. Hotate: “Distributed photonic sensing with synthesized optical coherence function,” SPIE International Congress on Optics and Optoelectronics, Vol.5952, Warsaw, pp.147-161, Aug.31- Sept.3, 2005 < Invited>. B8 K. Hotate: “Enlargement of measurement range in a Brillouin optical correlation domain analysis system using double lock-in amplifiers and a single-sideband modulator,”: “Photonic sensing,” MOC’05, TW2, p.6, Tokyo, Oct.30–Nov.2, 2005 (Tutorial) . B9 Z. He, S. Horie, K. Hotate, M. Ishikawa, and Y. Yoshikuni: “Unification of input and output ends in polarization-maintaining optical fiber stress sensor by synthesis of optical coherence function,” Proc. SPIE International Symposium on Optomechatronic Technologies (ISOT 2005), Vol.6049, pp. 25-36, Sapporo, Dec. 2005 . B10 A. Ohno, A. Kurokawa, T. Kumagai, S. Nakamura and K. Hotate: “Applications and technical progress of fiber optic gyros in Japan,” 18th Intern. Conf. on Optical Fiber Sensors (OFS-18), Cancun, MA4, Oct. 23 (23-27) 2006 . B11 K. Hotate: “Fiber-optiv nerve systems for non-destructive diagnosis of structures and materials,” Tenth Intern. Symp. on Contemporary Photonics Technology (CPT 2007), Tokyo, I-1, pp.127-128, Jan. 10-12, 2007 . B12 K. Hotate: “Fiber-Optic nerve systems for materials and structures that can feel pain,” World Forum on Smart Materials and Smart Structures Technology (SMSST 2007), Chonching, May 22-24, 2007 . B13 K. Hotate: “Fiber optic nerve systems for materials that can feel pain,” The European Conference on Lasers and Electro-Optics and the XIth European Quantum Electronics Conference (CLEO/Europe-IQEC 2007), Munich, CH1-3, June. 16-20, 2007 . B14 K. Hotate: “Fiber Optic Nerve Systems for materials and structures that can feel pain,” SMSST07, Tokyo, July 21-22, 2007 . B15 K. Hotate: “Fiber optic nerve systems for materials and structures that can feel pain,” 21st IEEE International Conference on Micro Electro Mechanical Systems (MEMS 2008), Tucson, pp.98-103, Jan. 15-18, 2008 . B16 K. Hotate: “Distributed optical fiber sensors and their applications,” 19th Intern. Conf. on Optical Fiber Sensors (OFS-19), Tutorial workshops, Perth, Apr. 14-18, 2008 . B17 K. Hotate: “Fiber optic nerve systems for smart materials and smart structures,” IEEE Topical Meeting on Microwave Photonics (NWP2008), Gold Coast, pp.31-34, Sept. 30 - Oct. 3, 2008 . B18 Z. He and K. Hotate: “Dynamic grating in optical fiber: synthesis and sensing applications,” 1st Asia-Pacific Optical Fiber Sensors Conference (APOS-2008), Chengdu, China, Nov. 7-9, 2008 . B19 K. Hotate: “Fiber optic nerve systems for safety and security,” SPIE Defense, Security, and Sensing, Orlando, April 13-17, 2009 .

- 4 - B20 K. Hotate and Z. He: “Fiber-Optic Nerve Systems for Safety and Security,” 4th Optoelectronics and Communications Conference, Hong Kong, July 13-17, 2009 . B21 K. Hotate: “Fiber optic nerve systems for smart materials and smart structures,” OSA Topical Meeting -Optical Sensors-, Karlsruhe, June 21-24, 2010 . B22 K. Hotate: “Fiber Optic Nerve Systems for Secure and Safety Society,” APOS’2010, Guangzhou, June 28-30, 2010 < Keynote>. B23 K. Hotate: “Fiber optic nerve systems for secure life and society,” 15th Optoelectronics and Communications Conference (OECC2010), Sapporo, July 5-9, 2010 . B24 K. Hotate: “Fiber optic distributed sensing for smart structures and smart materials,” 9th International Conference on Optical Internet 2010 (COIN 2010),Jeju, MoB2-1, July 11-14, 2010 .

C. Books (C1, from Aug. 2004 to Aug. 2010)

C1 K. Hotate: “Optical Fiber Sensors for Smart Materials/Structures and Optical Communications, (A Chapter in “New Photonics Technologies for the Information Age,”)” Artec House, pp.159-179, Dec. 2004.

D. Patents (D1-D7, from 2004 to 2010))

D1 K. Hotate, Ando Electric Co. Ltd, Kyusyu Ando Electric Company Limited: “Apparatus and method for measureing characteristics of optical fibers,” Inventor, K. Hotate and M. Kannou, Japan Patent, No. 3607930, Oct. 22, 2004. D2 K. Hotate, T. Hasegawa and H. Shimotahira: “Apparatus and Method for measuring Brillouin gain spectrum,” Inventor: K. Hotate, T. Hasegawa, H. Shimotahira, Proprietor: K. Hotate, T. Hasegawa, Anritsu Co., Japan Patent, No. 3667132, April 15, 2005. D3 K. Hotate, K.-Y. Song: “Optical fiber characteristic measuring apparatus and optical fiber characteristic measuring method,” Inventor: K. Hotate and, K.-Y. Song, Proprietor: The University of Tokyo, Japan Patent, No. 4100574, March 28, 2008. D4 K. Hotate, Ando Electric Co. Ltd, Kyusyu Ando Electric Company Limited: “Apparatus and method for measureing characteristics of optical fibers,” Inventor, K. Hotate and M. Kannou U.K. Patent, No. GB2381863, Mar. 17, 2004. D5 K. Hotate et. Al.: “Apparatus and method for measuring characteristics of optical fibers,” U.S. Patent, No. 6,710,863, Mar. 23, 2004. D6 K. Hotate et. Al.: “Apparatus and method for measuring characteristics of optical fibers,” Canada Patent, No. 2390048, Mar. 23, 2004. D7 K. Hotate, K.-Y. Song, Z. He: “Optical fiber characteristic measuring apparatus and optical fiber characteristic measuring method,” Inventor: K. Hotate and, K.-Y. Song, Z. He. Proprietor: Yokogawa Electric Corporation and the Univ. of Tokyo, U.K. Patent, No. GB2446761, Feb, 17, 2010.

E. Majour Research Grants obtained (E0, E1-E2, from Aug. 2004 to Aug. 2010)

E0 K. Hotate: “Fiber Optic Distributed Sensing Technologies with High Spatial Resolution and High Performance for Smart Materials, Structures and Communication Networks,” Grant-in-Aid for Specially Promoted Research, funded by Ministry Education, Culture, sports, Science and Technology (MEXT), Japan, 2001-2003. E1 K. Hotate; “Fiber Sensor Photonics for Safety and Security - Realization of ultimate performance in fiber optic nerve systems-,” Grant-in-Aid for Creative Scientific Research, funded by Ministry Education, Culture, sports, Science and Technology (MEXT), Japan, 2004-2008. E2 K. Hotate; “Functional Evolution of Fiber Optic Nerve Systems with Optical Correlation Domain Technique for Structures and Materials that can Feel Pain,” Grant-in-Aid for Scientific Research (S), funded by Ministry Education, Culture, sports, Science and Technology (MEXT), Japan, 2009-2013.

- 5 - Possible Referees for the nominee, Prof. Kazuo Hotate

[ 8 candidates ]

1) Prof. Byoung Yoon Kim Department of Physics Korea Advanced Institute of Science and Technology 373-1 Guseong-dong, Yuseong-gu, Daejeon, 305-701, Republic of Korea Tel: +82-42-869-2527, Fax: +82-42-869-5527 E-mail: [email protected]

2) Dr. Wolfgang Ecke IPHT - Institute of Photonic Technology Optical Fibers and Fiber Applications Albert-Einstein-Str. 9, D-07745 Jena, Germany Tel: +49-3641-206 220, Fax: +49-3641-206 297 E-mail: [email protected]

3) Dr. Alexis Mendez President, MCH Engineering, LLC 1728 Clinton Ave. Alameda, CA 94501, U.S.A. Tel: +1-510-521-1069 Fax: +1-510-521-5079 E-mail: [email protected]

4) Dr. Ryozo Yamauchi Fujikura Fellow Fujikura Ltd R&D Division 1-5-1 Kiba, Koto-ku, Tokyo 135-8512, Japan Tel: +81-3-5606-1060, Fax: +81-3-5606-1509 E-mail: [email protected]

5) Prof. David Sampson Winthrop Professor, School of Electrical, Electronic & Computer Engineering The University of Western Australia M018, 35 Stirling, Highway, Crawley, WA 6009, Australia Tel: +61-8-6488 2317 Assistant/ 7112 Direct, Fax: +61-8-6488 1319 E-mail: [email protected]

6) Prof. Julian D. C. Jones Deputy Principal for Strategy and Resources Heriot-Watt University Edinburgh EH14 4AS UK Tel: 0131 451 3031 E-mail: [email protected]

7) Dr. Gordon. Day Past President, IEEE Photonics Society U. S. A. E-mail: [email protected], [email protected]

8) Prof. Masamitsu Haruna Division of Medical Physics and Engineering Course of Health Science, Graduate School of Medicine, Osaka University 1-7 Yamada-Oka, Suita, Osaka 565-0871, Japan Tel: +81-6-6879-2572, Fax: +81-6-6879-2469 E-mail: [email protected]

INTERNATIONAL UNION OF RADIO SCIENCE

1. NAME OF CANDIDATE : LIN, James Chih-I...... Last, First, Middle

PRESENT OCCUPATION: Position, Organization

Professor Department of Electrical and Computer Engineering and Department of Bioengineering, University of Illinois at Chicago ......

BUSINESS ADDRESS :

851 South Morgan Street, M/C 154, Chicago, Illinois 60607 USA ......

HOME ADDRESS :

21 Camelot Drive, Oak Brook, Illinois 60523 USA: ......

BIRTHDATE December 29, 1942 NATIONALITY :USA ...... SEX : male - female (underline the appropriate)

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year

University of Washington Seattle Ph.D. 1971 University of Washington Seattle M.S. 1968 University of Washington Seattle B.S. 1966 ......

3. PROPOSED CITATION (not more than thirty words) ...... For contributions and leadership to the field of radio science in biology and medicine ......

4. NOMINATOR : Jørgen Bach Andersen ...... ADDRESS : Aalborg University, Niels Jernes vej 12 ...... 9220 Aalborg, Denmark ...... PHONE : +45 2856 2889 ...... FAX: ...... E-MAIL : [email protected] ...... 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

1980-Present, Professor of electrical engineering, bioengineering, physiology and biophysics University of Illinois, Chicago (Teaching, research, and service to profession and the public.)

1992-1994, Director of Special Projects, College of Engineering Univ of Illinois, Chicago (Lead and manage college’s liaison with industry and direct collaborative research projects)

1980-1992, Department Head and Professor, Dept. of Bioengineering, Univ of Illinois, Chicago. (Faculty leader, manage department, administed academic programs, teaching, research, and service to profession and the public.)

1982-1989, Director, Robotics and Automation Laboratory, College of Engineering, Univ of Illinois, Chicago. (Manage and lead laboratory research programs and provide service to profession and the public.)

1974-1980, Assistant, Associate and Professor, Dept. of Electrical & Computer Engineering, and Dept. of Physical Medicine & Rehabilitation, Wayne State Univ., Detroit. (Teaching, research, and service to profession and the public.)

1971-1974, Research Associate, Assistant Professor, Dept. of Rehabilitation Medicine, and Center for Bioengineering, Univ. of Washington, Seattle. (Teaching, research, and service to profession.)

6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

AWARDS: Best Paper Award, IEEE Transactions on Electromagnetic Compatibility 1975 (Lin, J.C., “Interaction of Electromagnetic Transient Radiation with Biological Materials,” IEEE Trans EMC. 17: 93-97). U.S. NIH National Research Services Award (1982) IEEE Committee on Man and Radiation, Special Recognition for Outstanding Achievement as Chair (1991) U.S. President's Committee on the National Medal of Science (1992-1993) Best Advisor Award, UIC Professional Engineering Societies Council (1993) NSC Research Chair (1993-1997) d’Arsonval Medal, the most prestigious award given by the Bioelectromagnetics Society (2003) Outstanding Leadership Award (1993), Chinese Academic and Professional Association in Mid-America. Listed in American Men and Women of Science, Who's Who in Engineering, Who's Who in America, and Who’s in the World, among others.

PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS: Bioelectromagnetics Society (President, 94-95, Board of Directors, 79-81;93-96, Editor-in- Chief, 2006-Present) Institute of Electrical and Electronic Engineers (IEEE Fellow, 1986); IEEE Committee on Man and Radiation (Chair, 1991-92); IEEE EMBS --AdCom (1986-88),Trans. Assoc. Editor (86-93), Guest Editor (1988), Internat Conf Program Chair (1985), Distinguished Lecturer (2009), and Fellows Com. (2003-present) American Association for the Advancement of Science (AAAS Fellow, 1989) American Institute for Medical and Biological Engineering (AIMBE Founding Fellow, 1992) U.S. National Council on Radiation Protection and Measurement (NCRP Scientific Vice President 2005-07); Committee on Biological Effects and Exposure Criteria for Radio Frequency Radiation (Chair, 1996-07) U.S. NAS-NRC - Task Force on Research Needs in Bioengg. Systems (1984-85), Review Committee on US Navy’s ELF Communication System Ecology Monitoring Program (1995- 97), US National Committee for URSI (1980-1982; 1991-02, Member of A, B, and K; Commission K, Chairman 1996-99) U.S. NIH Diagnostic Radiology Study Section (1981-85) and chaired many Special Emphasis Panels (1986- 2004). U.S. NSF Presidential Young Investigator Award Panel (1984, 89) Chinese American Academic and Professional Convention (President, 1993) International Union of Rado Science (URSI) Commission on Electromagnetics in Biology and Medicine (Chair, 1996-99; had major role in its creation); Long Range Planning Committee (1999-02; Standing Committee on Young Scientists (1999-02); Inter-Commission Working Group on Solar Power Satellite (Co-Chair, 2002-). URSI General Assemblies: Joint Symposium on Interaction of Electromagnetic Waves with Biological Systems, Tel Aviv, Israel, Chairman and Organizer, 1987; Convenor, Lille, France, 1996; Commission K Program Chairman, Toronto, Canada, 1999; Convenor, Maastricht, Netherlands, 2002; Convenor, New Dehli, India 2005. WHO (World Health Organiztion) International Advisory Committee on Electromagnetic Fields (2000-present) International Commission on Nonionizing Radiation Protection - ICNIRP (2004-present; Chairman of Standing Committee on Physics and Engineering, 2008-12) International ICST Conference on Wireless Mobile Communication and Healthcare (MobiHealth 2010), General Conference Chair October, 2010 Cyprus.

7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex – maximum 5 pages)

- Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions.

Authored 140 journal articles, 10 books, 27 book chapters, 104 columns, 59 conference proceedings and 269 abstracts of presentation. (see Annex for Selected Recent and Related Publications)

Books: 1. Lin JC. Microwave Auditory Effects and Applications. CC Thomas, Springfield, IL 1978. 2. Michaelson S, Lin JC Biological Effects And Health Implications Of Radiofrequency Radiation. Plenum Press, New York 1987 3. Lin JC. Ed. Electromagnetic Interaction With Biological Systems, Plenum Press, New York 1989 4. Lin JC. Ed. Advances In Electromagnetic Fields In Living Systems. (5 volumes) New York, (vol 1) 1994 Plenum; (vol 2) 1997; (vol 3) Kluwer, 2000; (vol 4) Springer, 2005; (vol 5: Health Effects of Cell Phone Radiation) Springer, 2009

Journal Articles:

1. Lin JC, Lin MF, Microwave hyperthermia-induced blood-brain barrier alterations, Radiation Research, 89:77-87, 1982. 2. Arber S. Lin JC, Microwave-Induced Changes in Nerve Cells: Effects of Modulation and Temperature, Bioelectromagnetics, 6:257-270, 1985 3. Lin JC, Microwave sensing of physiological movement and volume change, Bioelectromagnetics, 13:557-565, 1992 4. Lin JC, Wang YJ. The cap-slot catheter antenna for microwave ablation therapy, IEEE Trans. Biomed Engineering, 43: 657-660, 1996. (First to report on the use of microwave energy ablation for cardiac arrhythmias: Beckman KJ, Lin JC, Wang J, Illes RW, Papp MA, Hariman RJ. 1987. Production of reversible and irreversible atrioventricular block by microwave energy. Circulation 76: 1612). 5. Wang ZW, Lin JC, Mao WH, Liu WZ, Smith MB, Collins CM. SAR and Temperature: Simulations and Comparison to Regulatory Limits for MRI, J of Magnetic Resonance Imaging, 26:437-441, 2007.

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT v Balthasar van der Pol Gold Medal

John Howard Dellinger Gold Medal

Appleton Prize

Booker Gold Medal

Issac Koga Gold Medal 9. ARGUMENTS IN SUPPORT OF THE NOMINATION (Limit to this page)

The accomplishments, contributions and leadership of Professor James Lin, during the past 40 years, have been outstanding. He has provided not only a better understanding of biological responses and medical applications of electromagnetic radiation, but also a basis for setting exposure criteria and educating future generations of scientists and engineers through his published works.

James Lin’s innovative research in noninvasive microwave physiological sensing using wireless technology has led to new applications of microwave sensors in medicine and in managing the injured, including triage during emergencies (Lin JC. 1992. Microwave sensing of physiological movement and volume change. Bioelectromagnetics 13:557-565; plus 12 other articles). His work on vital sign sensing using wireless microwave technology launched a wide array of new noninvasive healthcare applications. It formed the basis of a significant part of DARPA’s (Defense Advanced Research Projects Agency?) proposed new development program (2009) on noninvasive continuous physiological status assessment in DoD (Department of Defense?) theater operations.

He pioneered the use of catheter microwave ablation therapy, especially for treating cardiac arrhythmias, which is rapidly becoming the minimally invasive treatment of choice and is making a demonstrable difference in the health and healing of people in the USA and throughout the world. Until recently, treatment consisted primarily of palliation, mainly in the form of pharmacological intervention. His contributions are marked by insights of cardiac electrophysiology and application of engineering rigor that allowed the creation of novel systems and new methodologies. (Lin JC, Wang YJ. 1996. The cap-slot catheter antenna for microwave ablation therapy. IEEE Trans Biomed Engineering 43: 657-660; plus 15 other articles). He was the first to report on the use of microwave energy ablation for cardiac arrhythmias (Beckman KJ, Lin JC, Wang J, Illes RW, Papp MA, Hariman RJ. 1987. Production of reversible and irreversible atrioventricular block by microwave energy. Circulation 76: 1612).

His seminal research on the mechanisms of microwave auditory effects is central to the development of bioelectromagnetics. His blending of rigorous analysis with imaginative experimental research provided new insights into a significant but poorly understood biological response, and provided a basis for current exposure criteria for pulse-modulated microwave radiation. He showed that the phenomenon does not arise from direct interactions with the central nervous system. Instead, the microwave pulse, upon absorption by soft tissues in the head, launches a thermoelastic wave of acoustic pressure that activates the inner ear receptors. Lin's elegant experimental and analytical studies of the theory of microwave-induced thermoelastic tissue interaction have made the microwave hearing phenomenon one of the most well defined and best understood effects of pulse-modulated microwave radiation. (Lin JC. Microwave Auditory Effects and Applications. Springfield, IL: CC Thomas; plus 24 other articles).

His most recent research focuses on ultra-high field strength magnetic resonance (MR) imaging modalities. The next generation of the MR imaging instrument is being developed and will provide increased spatial resolution for diagnostic radiology. These ultra-fast MR instruments operate at 7.0 T, 9.4 T, or higher, with corresponding RF frequencies of 300 MHz, 400 MHz or more, for proton imaging. His research is central to the production RF fields and their interactions inside biological bodies. (Wang ZW, Lin JC, Mao WH, Liu WZ, Smith MB, Collins CM. 2007. SAR and temperature: Simulations and comparison to regulatory limits for MRI. J of Magnetic Resonance Imaging 26(2):437-441; and Lin JC, Wang ZW. 2010. Acoustic pressure waves induced in human heads by RF pulses from high-field MRI scanners. Health Phys 98(4): 603-613).

Annex Selected Recent Publications (Since 2004):

1. Lin, J.C., Studies on Microwaves in Medicine and Biology: From Snails to Humans, Bioelectromagnetics, vol. 25, pp 146-159, 2004 2. Bernardi, P, M. Cavagnaro, J.C. Lin, S. Pisa, and E. Piuzzi. Distribution of SAR and Temperature Elevation Induced in a Phantom by a Microwave Cardiac Ablation Catheter, IEEE Trans. Microwave Theory and Techniques, vol. 52, pp.1978-1986, 2004 3. Lin, J.C., Microwave Thermoelastic Tomography and Imaging, Advances in Electromagnetic Fields in Living Systems, Springer, New York, vol. 4, pp. 41-76, 2005 4. Lin, J.C. and Z.W. Wang, SAR and Temperature Distributions in Canonical Head Models Exposed to Near- and Far-Field Electromagnetic Radiation at Different Frequencies, Electromagnetic Biology and Medicine, vol. 24 (3), pp. 405-421, 2005 5. Lin, J.C., Interaction of Wireless Communication Fields With the Blood-brain Barrier of Laboratory Animals, Radio Science Bulletin, No. 315, pp.33-38, 2005. 6. Lin, J.C., Biomedical Applications of Electromagnetic Engineering, In: R. Bansal, ed., Engineering Electromagnetics: Applications, Taylor & Francis, Boca Raton, Chapter 7, pp. 211-233, 2006 7. Lin J.C. and P. Bernardi, Computer Methods for Predicting Field Intensity and Temperature Change, in F. Barnes and B. Greenebaum, Eds., Bioengineering and Biophysical Aspects of Electromagnetic Fields, CRC Press, Boca Raton, FL., Chapter 10, pp. 293-380, 2007. 8. Lin, J.C., Dosimetric comparison between different possible quantities for limiting exposure in the RF band: Rationale for the basic one and implications for guidelines, Health Physics, 92(6):547-453, 2007 9. Lin, J.C.and Z.W. Wang, Hearing of Microwave Pulses by Humans and Animals: Effects, Mechanism, and Thresholds, Health Physics, 92(6):621-628, 2007 10. Wang, Z.W., J.C. Lin, W.H. Mao, W.Z Liu, M.B. Smith, and C.M. Collins, SAR and Temperature: Simulations and Comparison to Regulatory Limits for MRI, J of Magnetic Resonance Imaging, 26(2):437-441, 2007 11. Lin JC, Allen S, Anderson JB, Bassen H, Ikehata M, Leitgeb N, Pisa S, Watanabe S, Yamazaki K. ICNIRP statement on EMF-emitting new technologies. Health Phys. 94(4):376-392, 2008 12. Lin, J.C., P. Bernardi, S. Pisa, M. Cavagnaro, and E. Piuzzi, Antennas for Medical Therapy and Diagnostics, In: C. Balanis, ed., Modern Antenna Handbook, Wiley, Hoboken, NJ, pp 1377-1428, 2008 13. Lin, J.C., P. Bernardi, S. Pisa, M. Cavagnaro, and E. Piuzzi, Antennas for Biological Experiments, In: C. Balanis, ed., Modern Antenna Handbook, Wiley, Hoboken, NJ, pp 1429-1460, 2008 14. Wang Z.W., Lin J.C., Vaughan J.T., and Collins C.M., On Consideration of Physiological Response in Numerical Models of Temperature During MRI of the Human Head, J of Magnetic Resonance Imaging, 28(5):1303-1308, 2008 15. Vecchia P, Hietanen M, Ahlbom A, Anderson LE, Breitbart E, de Gruijl FR, Lin JC, Matthes R, Peralta AP, Sööderberg P, Stuck BE, Swerdlow AJ, Taki M, Saunders R, Veyret B, Swerdlow AJ, Chakeres DW, Feychting M, Hennig J, Tenforde TS, van Rongen E. ICNIRP Guidelines on limits of exposure to static magnetic fields. Health Phys. 96(4):504- 514, 2009 16. Lin, J.C., Carcinogenic Effect of Wireless Communication Radiation in Rodents, Advances in Electromagnetic Fields in Living Systems, Springer, New York, vol. 5, pp, 35-82, 2009 17. Bernardi, P., M. Cavagnaro, S. Pisa , E. Piuzzi, and J.C. Lin, Dosimetry and Temperature Aspects of Mobile Phone Exposures. Advances in Electromagnetic Fields in Living Systems, Springer, New York, vol. 5, pp 221-276, 2009 18. Lin, J.C., P. Bernardi, and J Bach Andersen, The Formation and Early Years of URSI Commission K on Electromagnetics in Biology and Medicine. Radio Science Bulletin, No. 330, pp. 51-59, 2009. 19. Vecchia P, Matthes R, Feychting M, Green A, Jokela K, Lin J, Peralta A, Saunders R, Schulmeister K, Söderberg P, Stuck B, Swerdlow A, Veyret B, Repacholi M, Ziegelberger G. ICNIRP statement on the Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields (up to 300 GHz). Health Phys. 97(3):257-258, 2009. 20. Vecchia P, Matthes R, Feychting M, Green A, Jokela K, Lin J, Peralta A, Saunders R, Schulmeister K, Söderberg P, Stuck B, Swerdlow A, Veyret B, Repacholi M, Ziegelberger G. Amendment to the ICNIRP Statement on medical magnetic resonance (MR) procedures: protection of patients. Health Phys. 97(3):259-261, 2009. 21. Vecchia P, R. Matthes, G. Ziegelberger, J. Lin, R. Saunders and A. Swerdlow, eds. Exposure to High Frequency Electromagnetic Fields, Biological Effects and Health Consequences (100 kHz-300 GHz) International Commission on Nonionizing Radiation Protection, ICNIRP-16, Munich, Germany, 2009 22. Lin, J.C. and Z.W. Wang, Acoustic Pressure Waves Induced In Human Heads by RF Pulses From High-Field MRI Scanners. Health Phys. 98(4): 603-613, 2010

Related Publications Cited in 7: Microwave Auditory Effect and Nicrowave Thermoacoustic (Thermoelastic) Imaging: 1. Lin, J.C., Microwave Auditory Effect--A Comparison of Some Possible Transduction Mechanisms, J. Microwave Power, vol. 11, pp. 77-81, March 1976. 2. Lin, J.C., Microwave Induced Hearing Sensation: Some Preliminary Theoretical Observations, J. Microwave Power, vol. 11, pp. 295-298, Sept. 1976. 3. Lin, J.C., On Microwave-Induced Hearing Sensation, IEEE Trans. Microwave Theory Techniques, vol. 25, pp. 605-613, July 1977 4. Lin, J.C., Further Studies on the Microwave Auditory Effects, IEEE Trans. Microwave Theory Tech., vol. 25, pp. 936-941, Nov. 1977 5. Lin, J.C., Calculations of Frequencies and Threshold of Microwave-Induced Auditory Signals, Radio Science Supplement, Biological Effects of Electromagnetic Waves, vol. 12/SS-1, pp. 237-252, Dec. 1977 6. Lin, J.C., R.J. Meltzer and F.K. Redding, Microwave-Evoked Brainstem Auditory Responses, Proc. Diego Biomed. Symp., vol. 17, Academic Press, pp 451-466, July 1978 7. Lin, J.C., R.J. Meltzer and F.K. Redding, Microwave-Evoked Brainstem Potential in Cats, J. Microwave Power, vol. 14, pp. 291-296, Sept. 1979 8. Lin, J.C., The Microwave Auditory Phenomenon, Proceedings of IEEE, vol. 68, pp. 67-73, Jan. 1980 9. Lin, J.C., The Microwave Hearing Effect, In Biological Effects of Nonionizing Radiation, K.H. Illinger, Ed., Amer. Chem. Soc., pp. 317-330, Sept. 1981 10. Olsen, R.G., and J.C. Lin, Microwave Pulse-Induced Acoustic Resonances in Spherical Head Models, IEEE Trans. Microwave Theory Tech., vol. 29, pp. 1114-1117, Oct. 1981 11. Lin, J.C., R.J. Meltzer and F.K. Redding, Comparison of Measured and Predicted Characteristics of Microwave-Induced Sound, Radio Science, vol. 17, pp. 159S-163S, Sept.- Oct. 1982 12. Olsen, R.B. and J.C. Lin, Microwave-Induced Pressure Wave in Mammalian Brain, IEEE Trans. Biomed. Engg., vol. 30, pp. 289-294, May 1983 13. Olsen, R.G. and J.C. Lin, Acoustical Imaging of a model of a Human Hand Using Pulsed Microwave Irradiation, Bioelectromagnetics, vol. 4, pp. 397-400, Dec. 1983 14. Lin, J.C., and K.H. Chan, Microwave Thermoelastic Tissue Imaging--System Design, IEEE Trans. Microwave Theory Tech., vol 32, pp. 854-860, Aug. 1984 15. Su, J.L. and J.C. Lin, "Thermoelastic Signatures of Tissue Phantom Absorption and Thermal Expansion, IEEE Transactions on Biomedical Engineering, vol. 34, pp. 179-182, February 1987 16. Lin, J.C., Su, J.L., Wang, Y.J., "Microwave-Induced Thermoelastic Pressure Wave Propagation in the Cat Brain," Bioelectromagnetics, vol. 9, pp. 141-147, April 1988 17. Lin, J.C., Auditory Perception of Pulsed Microwave Radiation. In: Biological Effects and Medical Applications of Electromagnetic Fields, O.P. Gandhi, Ed., Prentice-Hall, New York, 1990; Chapter 12, pp. 277-318 18. Lin, J.C., "Microwave Thermoelastic Tomography and Imaging," Advances in Electromagnetic Fields in Living Systems, Springer, New York, vol. 4, pp. 41-76, August, 2005 19. Lin, J.C. and Z.W. Wang, AHearing of Microwave Pulses by Humans and Animals: Effects, Mechanism, and Thresholds,@ Health Physics, 92(6):621-628 June 2007 20. Lin, J.C. and Z.W. Wang, Acoustic Pressure Waves Induced In Human Heads by RF Pulses From High-Field MRI Scanners. Health Phys. 98(4): 603-613, 2010 Microwave-induced Blood-Brain Barrier Alterations: 1. Lin, J.C. and M.F. Lin, Studies on Microwave and Blood-Brain Barrier Interaction, Bioelectromagnetics, vol. 1, pp. 313-323, 1980 2. Goldman, H., J.C. Lin, S. Murphy and M.F. Lin, Cerebrovascular Permeability to 86Rb in the Rat After Exposure to Pulsed Microwaves, Bioelectromagnetics, vol. 5, pp. 323-330, Sept. 1984 3. Neilly, J.P., and J.C. Lin, "Interaction of Ethanol and Microwaves on the Blood-Brain Barrier of Rats," Bioelectromagnetics, vol. 7 pp. 405-414 December 1986 4. Lin, J.C., P.M.K. Yuan and D.T. Jung, AEnhancement of Anticancer Drug Delivery to the Brain by Microwave Induced Hyperthermia,@ Bioelectrochemistry and Bioenergetics, vol. 47, pp 259-264, December, 1998 5. Lin, J.C., AInteraction of Wireless Communication Fields With the Blood-brain Barrier of Laboratory Animals, Radio Science Bulletin, No. 315, pp.33-38, December, 2005 Microwave Sensing of Physiological Signatures and Vital Signs: 1. Lin, J.C., Noninvasive Microwave Measurement of Respiration, Proc. IEEE, vol. 63, pp. 1530, October 1975 2. Lin, J.C., E. Dawe and J. Majcherek, A Noninvasive Microwave Apnea Detector, Proceedings 1977 San Diego Biomedical Symposium, Academic Press, 1977, pp. 441-443 3. Lin, J.C., J. Kiernicki, M. Kiernicki and P.B. Wollschlaeger, Microwave Apexcardiography, IEEE Trans. Microwave Theory and Tech., vol. 27, pp. 618-620, June 1979 4. Lin, J.C. and M.J. Clarke, Microwave Imaging of Cerebral Edema, Proc. IEEE, vol. 70, pp. 523-54, May 1982 5. Clarke, M.J. and J.C. Lin, Microwave Sensing of Increased Intracranial Water Content, Invest. Radiol., vol. 18, pp. 245-248, June 1983 6. Lee, J.Y. and J.C. Lin, A Microprocessor Based Non-Invasive Pulse Wave Analyzer, IEEE Trans. Biomed. Engg., vol. 32, pp. 451-455, June 1985 7. Lin, J.C., Microwave Propagation in Biological Dielectrics with Application to Cardiopulmonary Interrogation, In Medical Applications of Microwave Imaging, L.E. Larsen and J.H. Jacobi Ed., New York IEEE Press pp. 47-58, 1986 8. Chan, K.H. and J.C. Lin, "Microprocessor Based Cardiopulmonary Rate Monitor," Med Biol. Engg and Computing, vol. 25, pp. 41-44, January 1987 9. Papp, M.A., C. Hughes, J.C. Lin and J.M. Pouget, "Doppler Microwave: A Clinical Assessment of Its Efficacy as an Arterial Pulse Sensing Technique," Invest. Radiol, vol. 22, pp. 569-573, 1987 10. Lin, J.C., "Microwave Noninvasive Sensing of Physiological Signatures," In Electromagnetic Interaction with Biological Systems, Ed., James C. Lin, Plenum, New York, pp. 3-25, 1989 11. Lin, J.C., "Diagnostic Applications of Electromagnetic Fields," In: Review of Radio Science 1992, Ross Stone, ed., Oxford Univ. Press, Oxford, August, 1993, pp 771- 778 12. Lin JC, Applying Telecommunication Technology to Health-Care Delivery. IEEE Engineering in Medicine and Biology. 18:28-31, 1999. Microwave-Induced Changes in Nerve Cells: 1. Lin, J.C. and Arber, S.L., Noise-Modulated-Microwave-Induced Response in Snail Neurons, Phy. Chem. and Physics and Medical NMR, vol. 15, pp. 261-263, Dec. 1983 2. Arber, S.L. and J.C. Lin, Microwave Enhancement of Membrane Conductance in Snail Neurons: Role of Temperature, Phy. Chem. and Physics and Medical NMR, vol. 15, pp. 259-260, Dec. 1983 3. O'Neill, W.D. and J.C. Lin, An Information Channel Model of a Neuron Encoder and Possible Microwave Radiation Effects on Capacity, IEEE Trans. System, Man and Cybernetics, vol. 14, pp. 717-725, Sept./Oct. 1984. 4. Arber, S.L. and J.C. Lin, Microwave Enhancement of Membrane Conductance: Effects of EDTA, Caffeine and Tetracaine, Phys. Chem. and Phy. and Med. NMR, vol. 16, pp. 469- 475, 1984 5. Arber, S. and J.C. Lin, Extracellular Calcium and Microwave Enhancement of Conductance in Snail Neurons, Radiation Environm. Biophysics, vol. 24, pp. 149-156, 1985 6. Arber, S. and J.C. Lin, Tetracaine and Possible Snail Neuron Plasma Membrane Thickening, Physiol. Chem. Phys. and Med. NMR, vol. 17, pp. 297-301, 1985 7. Arber, S., J. Neilly, R. Becker, V. Kriho and J.C. Lin, Pigmented Granules and Microwave Enhancement of Membrane Conductance in Snail Neurons, Physiological Chemistry and Physics and Medical NMR, vol. 17, pp. 301-305, 1985 8. O'Neill, W.D., J.C. Lin and Y.C. Ma, Estimation and Verification of a Stochastic Neuron Model, IEEE Transactions on Biomedical Engineering, vol. BME-33, pp. 654-666, July 1986 9. Arber, S.L., J.P. Neilly, J.C. Lin and V. Kriho, "The Effect of 2450 MHz Microwave Radiation on the Ultrastructure of Snail Neurons," Physiological Chemistry and Physics and Medical NMR, vol. 18, pp. 243-249, December 1986 10. Ginsburg, K, J.C. Lin, W.D. O'Neill, "Microwave Effects on Input Resistance and Action Potential Firing of Snail Neurons, IEEE Trans on Biomedical Engineering, vol. 39, pp 1011- 21, October, 1992 11. Lin, J.C., "Neuronal Interactions of Amplitude-Modulated 2450 MHz Microwave Radiation," Neural Network World, vol. 5, pp 789-793, 1995 Catheter Microwave Ablation Therapy for Cardiac Arrhythmias and Hyperthermia: 1. Lin, J.C., Engineering and Biophysical Aspects of Microwave and Radio-Frequency Radiation, in Hyperthermia, D.J. Watmough and W.M. Ross, Eds., Glasgow, Blackie, pp. 42-75, 1986 2. Lin, J.C. and Y.J. Wang, "Interstitial Microwave Antennas for Thermal Therapy," Int. J. Hyperthermia, vol. 3, pp. 37-47, January 1987 3. Lin, J.C. and Y.J. Wang, "An Implantable Microwave Antenna for Interstitial Hyperthermia," Proceeding of the IEEE, vol. 75, no. 8, pp. 1132-1133, August 1987 4. Lin, J.C., Transcatheter Microwave Technology for Treatment of Cardiovascular Diseases. In: Emerging Electromagnetic Medicine (Eds. M.E. O'Connor, R.H.C. Bentall, J.C. Monahan). Springer-Verlag, New York, 1990, pp. 125-134 5. Lin, J.C., Y.J. Wang, R.J. Hariman, "Comparison of Power Deposition Patterns Produced by Microwave and Radio Frequency Cardiac Ablation Catheters ," Electronics Letters, vol. 30, pp 922-923, June, 1994 6. Lin, J.C. and Y. Wang, "A Catheter Antenna for Percutaneous Microwave Therapy," Microwave and Optical Technology Letters, vol. 8, pp 70-72, Feb. 1995 7. Lin, J.C., K.J. Beckman, R.J. Hariman, S. Bharati, M. Lev, Y.J. Wang, "Microwave Ablation of the Atrioventricular Junction in Open Heart Dogs," Bioelectromagnetics, vol. 16, pp 97-105, April, 1995 8. Lin, J.C., and Y.J. Wang, "The Cap-Slot Catheter Antenna For Microwave Ablation Therapy," IEEE Trans. Biomed Engineering, vol. 43, pp 657-660, June, 1996 9. Lin, J.C., R.J. Hariman, Y.G. Wang, and Y.J. Wang, "Microwave Catheter Ablation of the Atrioventricular Junction in Closed-Chest Dogs," Medical & Biological Engineering & Computing, vol. 34, pp 295-298, July, 1996 10. Lin JC, Catheter Microwave Ablation Therapy for Cardiac Arrhythmias,@ Bioelectromagnetics, 20:120s-132s, 1999. 11. Lin, J.C., "Hyperthermia Therapy," In: Encyclopedia of Electrical and Electronics Engineering, J. G. Webster, ed., Wiley, New York, May, 1999, vol. 9, pp 450-460 12. Lin, J.C., "Biophysics of Radiofrequency Ablation," In: S. K.S. Huang and D.J. Wilber , eds., Radiofrequency Catheter Ablation of Cardiac Arrhythmias: Basic Concepts and Clinical Applications, 2nd ed, Futura, Armonk, New York, May, 2000 pp 13-24 13. Pisa, S., M. Cavagnaro, P. Bernardi, and J.C. Lin, A 915-MHz Antenna for Microwave Thermal Ablation Treatment: Physical Design, Computer Modeling and Experimental Measurement,@ IEEE Trans. Biomed Engineering, vol. 48, pp 599-601, May, 2001 14. Pisa, S., M. Cavagnaro, E. Piuzzi, P. Bernardi, and J.C. Lin, Power Density and Temperature Distributions Produced by Interstitial Arrays of Sleeved-slot Antennas for Hyperthermic Cancer Therapy,@ IEEE Trans. Microwave Theory and Techniques, vol. 51, pp. 2418-2426, December 2003 15. Lin, J.C., AMinimally Invasive Medical Microwave Ablation Technology,@ In: Hwang N.H.C. and Woo S.L.Y. eds., New Frontiers in Biomedical Engineering, Kluwer/Plenum, New York, Chapter 36, pp.545-562, December, 2003 16. Bernardi, P., M. Cavagnaro, J.C. Lin, S. Pisa, and E. Piuzzi ADistribution of SAR and Temperature Elevation Induced in a Phantom by a Microwave Cardiac Ablation Catheter,@ IEEE Trans. Microwave Theory and Techniques, vol. 52, pp.1978-1986, August 2004 17. Lin, J.C., P. Bernardi, S. Pisa, M. Cavagnaro, and E. Piuzzi, “Antennas for Medical Therapy and Diagnostics,” In: C. Balanis, ed., Modern Antenna Handbook, Wiley, Hoboken, NJ, pp 1377-1428, August 2008 Possible Referees for James Chih-I. LIN

Prof. H. Matsumoto : [email protected]

Prof. A. Ishimaru : [email protected]

Dr. Ross Stone : [email protected]

Prof. Paolo Bernardi : [email protected]

INTERNATIONAL UNION OF RADIO SCIENCE

1. NAME OF CANDIDATE: MAYSTRE, Daniel, Raymond......

PRESENT OCCUPATION: Director of Research ...... CNRS (French National Center for Scientific Research)......

BUSINESS ADDRESS: Institut Fresnel, Domaine Universitaire de St Jérôme, Avenue Escadrille Normandie-Niemen, F 13397 Marseille Cedex 20 (France)......

HOME ADDRESS: Résidence Plein-Sud 1 (B4) F 13380 Plan de Cuques (France)......

BIRTHDATE 27 March 1945 NATIONALITY: French……………SEX: male - female

2. EDUCATION (Honorary degrees denoted by H) 1964-1968: Graduate studies at Ecole Normale Supérieure (St Cloud, Paris)...... 1968 Agrégation of Physics ...... 1974 Thèse d’Etat (State Thesis) ......

3. PROPOSED CITATION (not more than thirty words) For his leadership in the development of diffraction gratings and inverse scattering, rigorous theory of scattering from random surfaces and metamaterials.

4. NOMINATOR: Joe Wiart, President of the French URSI Committee ...... ADDRESS: Orange Labs, 38-40, rue du Général Leclerc, F-92131 Issy les Moulineaux PHONE: +33 1 45 29 58 44...... FAX: +33 1 45 29 41 94...... E-MAIL : [email protected] , [email protected] ......

1 page 2 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

From (year) to (year) Name of Company/Institution Position and Responsibilities

2004 2010 CNRS Director of Research with Exceptional Class

1990 2003 CNRS Director of Research 1st class

1976 1989 CNRS Director of Research 2nd class

1968 1975 CNRS Researcher

2 page 3 6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

2009 Medal of URSI France...... 1998 Scientific Philip Morris Prize...... 1975 Fabry de Gramont Prize (given by the Optical French Society) 2008- 2010 Member of the Scientific Committee of CEA (French Atomic Studies Center) 2008-2010 President of the experts committee of CEA (Military division) for Electromagnetics. 2000-2004 Member of the National Committee of CNRS 1980-1981 Associate researcher in the National Bureau of Standards (Washington DC, invitation of the National Science Foundation) in the Surface characterization group ...... Member of the French Society of Optics Member of the Optical Society of America ...... Member of URSI France...... Expert of NASA Expert of the Australian Ministry of Education ...... Expert of Bar-Ilan University (Israel)...... Reviewer of most of the international journals of Electromagnetics and Optics ......

7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex – maximum 5 pages)

- Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions.

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT

Balthasar van der Pol Gold Medal

John Howard Dellinger Gold Medal

Appleton Prize

Booker Gold Medal

Issac Koga Gold Medal

3 page 4 9. ARGUMENTS IN SUPPORT OF THE NOMINATION (Limit to this page)

Initially, Daniel Maystre was almost exclusively devoted to the theoretical and numerical study of diffraction gratings. The discovery of an original integral equation has enabled him to develop the first digital code that can calculate precisely the properties of gratings in the visible, infrared and ultraviolet. Improved over time, this code is used today by a score of industrial centers and university laboratories worldwide. It allowed, in the early 70s to explore the properties of the first holographic gratings and optimize the properties of the first networks on satellites in the emerging Space optics.

Daniel Maystre developed the first quantitative phenomenological theory of the "Wood anomalies" diffraction gratings, based on the properties of surface plasmons. He has discovered and verified experimentally the phenomenon of total absorption of an incident wave by a metallic grating. He subsequently modelled photonic crystals and photonic crystal fibers. He was among the first to introduce the inverse scattering in optics and electromagnetism and to develop a rigorous theory of diffraction from random rough surfaces.

Finally, more recently, Daniel Maystre has been interested in metamaterials. It has been shown mathematically by him that a homogeneous “left hand” material of permeability and permittivity simultaneously negative could not exist but nevertheless that the concept of "superlens" was not a purely theoretical view.

4

Annex: Principal publications, Patents

3 books, 15 chapters, 240 papers in international journals, 63 invited conferences in international symposia, 5 patents

Books

"Modern Analysis of Scattering Phenomena" Ed. D. MAYSTRE and J.C. DAINTY, Adam Hilger, Bristol, 1991 (190 pages) "Diffraction Gratings" Ed. D. MAYSTRE, SPIE Milestones series, SPIE Optical Engineering Press Bellingham, Washington, USA, 1993 (679 pages) "Photonic crystals: towards wavelength scale photonic devices". H. Benisty, V. Berger, A. Chelnokov, J.M. Gérard, J.M. Lourtioz, D. Maystre Springer Verlag, 2005 (first edition), 2008 (second edition).

Some Chapters

"Integral methods", D. MAYSTRE, chapter 3 (pp. 63-100) of :"Electromagnetic Theory of Gratings", R. PETIT Ed., Springer-Verlag (1980). "Expérimental verifications and applications of the theory", D. MAYSTRE, M. NEVIERE, R. PETIT, chapter 6 (pp. 159-225) of "Electromagnetic Theory of Gratings" R. PETIT Ed., Springer-Verlag (1980). "General study of grating anomalies from electromagnetic surface modes", D. MAYSTRE, Chapter 17 (pp. 661-724) of "Electromagnetic Surface Modes", A. BOARDMAN Ed., John Wiley & Sons (1982). "Rigorous vector theories of diffraction gratings", D. MAYSTRE, Chapter 1 (pp. 3-67) of "Progress in Optics" (Vol. 21) E. WOLF Ed., North Holland Publishing Company (1984). "Rigorous solution of problems of scattering by large size objects", D. MAYSTRE and M. SAILLARD, in "Scattering in Volumes and Surfaces" (pp. 191-208), M. NIETO-VESPERINAS and J.C. DAINTY Ed., Elsevier (1990). "Light scattering by Solid surfaces and surface characterization" D. MAYSTRE, in "Light scattering by liquid surfaces and complementary techniques" (pp. 427-443), D. LANGEVIN Ed., Marcel Dekker (1992). "A finite-elements method for electromagnetic subsurface tomography" M. SAILLARD, P. VINCENT and D. MAYSTRE, Chapter 11 (pp. 237-264) of "Finite Element Software for Microwave Engineering", T. Itoh, G. Pelosi et P.P. Silvester Ed., Wiley, New York (1996). "Special methods of wave diffraction" D. MAYSTRE, M. SAILLARD, G. TAYEB, in "Scattering", P. Sabatier and E.R. Pike Ed.(pp. 366-393), Academic Press, London (2002). “Scattering Matrix Method Applied to Photonic Crystals”

5 D. MAYSTRE, S. ENOCH, G. TAYEB, in "Electromagnetic Theory of Photonic Crystals", Ed. K. Yasumoto (pp. 1-46), M. Dekker (2006). “Diffraction : les fondements électromagnétiques », D. MAYSTRE, in « Optique Physique » (pp. 19-58) Hermès Science (2003). « Les cristaux photoniques », J.M. LOURTIOZ, D. MAYSTRE, J.M. GERARD, H. BENISTY, A. CHELNOKOV, V. BERGER (432 pages) Hermès Science (2003). In print: “History of Plasmonics”, D. MAYSTRE, in Introduction to Plasmonics, Ed. N. Bonod et S. Enoch, Springer (about 40 pages). In print: “Wood’s anomalies”, D. MAYSTRE, in Introduction to Plasmonics, Ed. N. Bonod et S. Enoch, Springer (about 60 pages).

Some publications

Essai de détermination théorique du profil optimal d'un réseau holographique. D. MAYSTRE et R. PETIT Opt. Commun., 4 (1971), p. 25-28 Diffraction d'une onde électromagnétique plane par un objet cylindrique non infiniment conducteur de section arbitraire. D. MAYSTRE et P. VINCENT Opt. Commun., 5 (1972), p. 327-330 Inadequacy of perfect reflectivity models for holographics gratings even in the visible region. R.C. Mc PHEDRAN and D. MAYSTRE Journal of the Spectroscopical Soc. of Japan, 23 (1974), p. 13-20. Correlation between efficiency of diffraction gratings and theoretical calculations over a wide range. E.G. LOEWEN, D. MAYSTRE, R.C. Mc PHEDRAN and I. WILSON, Japanese Journal of Applied Physics, 14 (1975), p. 143-152. Brewster incidence for metallic gratings. D. MAYSTRE and R. PETIT Opt. Commun., 17 (1976), p. 196-200. On the efficiencies of rectangular-groove gratings. J.L. ROUMIGUIERES, D. MAYSTRE and R. PETIT J. Opt. Soc. Am., 66 (1976), p. 772-775. Optical design for beam sampling mirror gratings. E.G. LOEWEN, M. NEVIERE and D. MAYSTRE Applied Optics, 15 (1976), p. 2937-2938.

The total absorption of light by a diffraction grating. M.C. HUTLEY and D. MAYSTRE Opt. Commun., 19 (1976), p. 431-436.

On the theory and solar application of inductive grids. R.C. Mc PHEDRAN and D. MAYSTRE Applied Physics, 14 (1977), p. 1-10.

Grating efficiency theory as it applies to blazed and holographic gratings. E.G. LOEWEN, M. NEVIERE and D. MAYSTRE Applied Optics, 16 (1977), p. 2711-2721.

6 On the use of classical and conical diffraction mountings for vacuum UV and XUV gratings. M. NEVIERE, D. MAYSTRE and R.W. HUNTER J. Opt. Soc. Am., 68 (1978), p. 1106-1113. A new general integral theory for dielectric coated gratings. D. MAYSTRE J. Opt. Soc. Am., 68 (1978), p. 490-495. On a general theory of anomalies and energy absorption by diffraction gratings and their relation with surface waves. D. MAYSTRE, M. NEVIERE and P. VINCENT Optica Acta, 25 (1978), p. 905-915. On a problem of inverse scattering in Optics : the dielectric inhomogeneous medium. A. ROGER, D. MAYSTRE and M. CADILHAC J. Optics, 9 (1978), p. 83-90. A new theory for multiprofile buried gratings. D. MAYSTRE Opt. Commun., 26 (1978), p. 127-132. Crossed gratings : a theory and its applications. G.H. DERRICK , R.C. Mc PHEDRAN, D. MAYSTRE and M. NEVIERE Applied Physics, 18 (1979), p. 39-52.

Inverse scattering method in Optics : application to diffraction gratings. A. ROGER and D. MAYSTRE J. Opt. Soc. Am., 70 (1980), p. 1483-1495.

Inductive grids in the region of diffraction anomalies : theory, experiment and applications. P. BLIEK, L.C. BOTTEN, R. DELEUIL, R.C. Mc PHEDRAN, D. MAYSTRE IEEE Microwave Theory and Techniques, 28 (1980), p. 1119-1125. A phenomenological theory for gratings, perfect blazing for polarized light in non-zero deviation mounting. D. MAYSTRE, M. CADILHAC Radio Science, 16 (1981), p. 1003-1008. Multicoated gratings : a differential formalism applicable in the entire optical region. J. CHANDEZON, M.T. DUPUIS, G. CORNET, D. MAYSTRE J. Opt. Soc. Am., 72 (1982), p. 839-846. Dyadic Green functions for the time-dependant wave equation. E. MARX and D. MAYSTRE Journal of Mathematical Physics, 23 (1982), p. 1047-1056.

Electromagnetic scattering from perfectly conducting rough surfaces in the resonance region. D. MAYSTRE IEEE Ant. and Prop., 31 (1983), p. 885-895.

An approximate theory of scattering from arbitrary rough surfaces. Phenomenon or short coupling range. D. MAYSTRE Proc. Intern. URSI Symposium (1983), p. 651-654, ISBN : 84-7191-305-4.

7 Theoretical and experimental study of the resonant frequency of a cylindrical dielectric resonator. D. MAYSTRE, P. VINCENT, J.C. MAGE IEEE Microwave Theory and Techniques, 31 (1983), p. 844-848. Surface enhanced second harmonic generation at a silver grating : a numerical study. M. NEVIERE, R. REINISCH, D. MAYSTRE Physical Review B, 32 (1985), p. 3634-3641.

Singularities of the continuation of the fields and validity of Rayleigh's hypothesis. D. MAYSTRE and M. CADILHAC Journal of Mathematical Physics, 26 (1985), p. 2201-2204.

Rigorous numerical study of speckle patterns for two-dimensional random microrough surfaces. J.P. ROSSI, D. MAYSTRE Optical Engineering, 25 (1986), p. 613-617.. Implementation of a rigorous vector theory of speckle for 2D microrough surfaces. D. MAYSTRE, J.P. ROSSI J. Opt. Soc. Am., 3 (1986), p. 1276-1282. Nonlinear polarization inside metals : a mathematical study of the free electron model. D. MAYSTRE, M. NEVIERE, R. REINISCH Applied Physics A, 39 (1986), p. 115-121. Scattering from metallic and dielectric rough surfaces M. SAILLARD, D. MAYSTRE J. Opt. Soc. Am. A, (1990) 7, 6, 982-990. Finite-elements method for gratings. T. DELORT, D. MAYSTRE. J. Opt. Soc. Am. A. 10, (1994),p. 2592-2601. Localization of light by randomly rough surfaces : concept of localiton. D. MAYSTRE, M. SAILLARD J. Opt. Soc. Am. A, Vol. 11, n° 2, 1994, 680-690. Scattering by a random set of parallel cylinders D. FELBACQ, G. TAYEB, D. MAYSTRE J. Opt. Soc. Am. A, 11,9, 1994, 2526-2538. Blazed holographic grating efficiency - numerical comparison with different profiles E. POPOV, B. BOZKOV, M. SABERA, D. MAYSTRE Opt. Commun., 1995, 117, 413-416. Scattering by lacunary gratings. G. GUIDA, G. TAYEB and D. MAYSTRE Journal of Modern Optics, Vol. 3, 1996, 2463-2483. Diffraction efficiency of echelles working in extremely high orders. E. LOEWEN, D. MAYSTRE, E. POPOV and L. TSONEV. Applied Optics, 35, 1996, 1700-1704. Enhanced normal scattering by lacunary gratings. G. GUIDA, D. MAYSTRE, G. TAYEB Journal of the Optical Society of America A, 14, 1997, 430-436.

Rigorous theoretical study of finite size two-dimensional photonic crystals doped by microcavities, G. TAYEB, D. MAYSTRE

8 J. Opt. Soc. Am. A, 14, 1997, 3323-3332.

Waterman and Rayleigh methods : improvement of the convergence domain. M. BAGIEU and D. MAYSTRE. Journal of the Optical Society of America A, 15, 1998, 1566-1576. Homogenization of two dimensional metallic photonic crystals. G. GUIDA, D. MAYSTRE, G. TAYEB and P. VINCENT. Journal of the Optical Society of America B, 15, 1998, 2308-2315. Electromagnetic modelling of three-dimensional metallic photonic crystals. G. GUIDA, D. MAYSTRE, G. TAYEB and P. VINCENT. Journal of Electromagnetic Waves and Applications, 12, 1998, 1153-1179. Numerical evidence of ultrarefractive optics in photonic crystals S. ENOCH, G. TAYEB and D. MAYSTRE Optics Communications, 161, 1999, 47-55. Regularized Waterman and Rayleigh methods : extension to two-dimensional gratings. M. BAGIEU and D. MAYSTRE, Journal of the Optical Society of America A, 16, 1999, 284-292. Experimental and theoretical study of resonant microcavities in two-dimensional photonic crystals. P. SABOUROUX, G. TAYEB and D. MAYSTRE Optics Communications, 160, 1999, 33-36. Axis-expansion method for nearly two-dimensional objects M. BAGIEU and D. MAYSTRE Progress In Electromagnetic Research, 26, 2000, 113-134. Symmetry properties of the field transmitted by inductive grids A. SENTENAC, PH. LALANNE, D. MAYSTRE, Journal of Modern Optics, 47, 2000, p. 2323-2333. Photonic crystal diffraction gratings D. MAYSTRE, Optics Express, 8, 2001, p. 209-216

Multipole method for microstructured optical fibers I: Formulation T.P. White, B.T. Kuhlmey, R.C. Mc Phedran, D. Maystre, G. Renversez, C. Martijn de Stercke, L.C. Botten J. Opt. Soc. Am. B, 10(19), p. 2322-2330, 2002

Multipole method for microstructured optical fibers II: implementation and results B.T. Kuhlmey, T.P. White, G. Renversez, D. Maystre, L.C. Botten, C. Martijn de Stercke, R.C. Mc Phedran, J. Opt. Soc. Am. B, 10(19), p. 2331-2340, 2002 Microstructured Optical fibers: where's the edge. B. Kuhlmey, M. de Sterke, R. C. McPhedran, P. Robinson, G. Renversez, and D. Maystre. Optics Express, 10(22), p. 1285-1290, 2002 Electromagnetic analysis of ultra-refraction and negative refraction D. MAYSTRE Journal of Modern Optics 50 1431-1444 (2003) Theoretical study of photonic bandgaps in woodpile crystals B. Gralak, M. de Dood, G. Tayeb, S. Enoch, D. Maystre Phys. Rev. E, 67 066601 (2003).

9

Perfect lenses made with left-handed materials: Alice’s mirror? D. Maystre and S. Enoch Journal of the Optical Society of America A 21 122-131 (2004).

Electromagnetic scattering by a set of objects: an integral method based on scattering operator, D. Maystre, Progress in Electromagnetic Research, PIER57, 55-84, 2006. Getting effective permittivity and permeability equal to –1 in 1D dielectric photonic crystals, D. Maystre, Journal of Modern Optics 53, 1901-1917 (2006)

Making photonic crystals using trapping and binding optical forces on particles D. Maystre and P. Vincent, Journal of Optics A: Pure and Applied Optics, 8, pp. 1059-1066 (2006)

Photonic crystal lens: from negative refraction and negative index to negative permittivity and permeability, Th. Decoopman , G. Tayeb, S. Enoch, D. Maystre and B. Gralak, Physical Review Letters, 97, 073905 (2006)

Electromagnetic scattering by a set of objects: an integral method based on scattering operator, D. Maystre, Progress In Electromagnetics Research 57, pp. 55-84 (2006). Enhanced SPR sensitivity using periodic metallic structures Colin J. Alleyne, Andrew G. Kirk1, Ross C. McPhedran, Nicolae-Alexandru P. Nicorovici, and Daniel Maystre Optics Express 15, 8163-8169 (2007) Phenomenological study of binding in optically trapped photonic crystals D. Maystre, P. Vincent J. Opt. Soc. Am. A, 24, pp. 2383-2393 (2007) Are optical forces derived from a scalar potential? D. Maystre, P. Vincent Optics Express, 15, pp. 9817-9830 (2007) Narrow-band filtering with whispering modes in gratings made of fibers A.L. Fehrembach, E. Popov, G. Tayeb, and D. Maystre Optics Express, 15, pp.15734-15740 (2007) Total absorption of unpolarized light by crossed gratings, E. Popov, D. Maystre, R.C. McPhedran, M. Nevière, M.C. Hutley, G.H. Derrick, Optics Express, 16, pp.6146-6155 (2008) Why a harmonic solution for lossless, perfectly homogeneous, left-handed material cannot exist D. Maystre, S. Enoch, R.C. McPhedran J. Opt. Soc. Am. A, 25, pp. 1937-1943 (2008) Total absorption of light by lamellar metallic gratings in conical mounting N. Bonod, G. Tayeb, D. Maystre, S. Enoch and E. Popov,

10 Optics Express 16, pp. 15431-15438 (2008) Fictitious Rayleigh expansions Daniel Maystre*, Wojciech Smigaj, Boris Gralak, Journal of Modern Optics, 56, pp.1403 - 1410 (2009) Linearly damped modes at gap edges of photonic crystals Daniel Maystre and Jean-Paul Hugonin, J. Opt. Soc. Am. A 27, pp.1069-1078 (2010)

Patents

Filtre optique de longueur d'onde.n° 72-07-310, D. MAYSTRE and R. PETIT. Nouveau mode d'utilisation des réseaux, n° 79-22554, D. MAYSTRE et R. PETIT. Holografiskt diffracktionsgitter, Svensk Patent 790-713-87, M. BREIDNE, D. MAYSTRE, S. JOHANSSON, K. BIEDERMANN.

11

INTERNATIONAL UNION OF RADIO SCIENCE

1. NAME OF CANDIDATE : MIR, Lluis, M.

PRESENT OCCUPATION : Tenured (DR1) researcher, CNRS (National Center for Scientific Research) ...... Director of the laboratory of Vectorology and Anticancer Therapies – Joint Research Unit (UMR) 8203 of the CNRS, University of Paris-Sud, and Institut Gustave-Roussy......

BUSINESS ADDRESS : UMR 8203 CNRS - Institut Gustave-Roussy 114 Rue Edouard Vaillant – F-94805 VILLEJUIF cedex - FRANCE......

HOME ADDRESS : 22 Allée des Vaupépins, F-91370 VERRIERES LE BUISSON, France

BIRTHDATE 27/06/1954 .....NATIONALITY : French...... SEX : male - female

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year Ecole Normale Supérieure de la rue d'Ulm, Paris, France ... 1974- 78 University of Paris VI Paris, France B.S. 1976 University of Paris VI and Pasteur Institute, Paris, France M.S. 1977 University of Toulouse III Toulouse, France M.S. 1978 University of Toulouse III Toulouse, France D.Sc. 1983

H - University of Ljubljana Ljubljana, Slovenia Senator h.c. 2004

3. PROPOSED CITATION (not more than thirty words) For the leadership in the development of the antitumor electrochemotherapy from inception to routine use in clinical applications

4. NOMINATOR: Joe Wiart, President of the French URSI Committee ...... ADDRESS: Orange Labs, 38-40, rue du Général Leclerc, F-92131 Issy les Moulineaux PHONE: +33 1 45 29 58 44...... FAX: +33 1 45 29 41 94...... E-MAIL : [email protected] , [email protected] ...... 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

From-To Name of Company/Institution Position and Responsibilities (years) Since 2010 CNRS (Centre National de la Recherche Tenured researcher DR1 (1st class) Scientifique) - Joint Research Unit (UMR) Director of the Laboratory of 8203 CNRS, University Paris-Sud, Institut Vectorology and Anticancer Therapies Gustave-Roussy, Villejuif, France From 2004 University of Ljubljana, Slovenia Adjunct professor 2002-2009 Tenured researcher DR 2nd class then 1st CNRS - UMR 8121 CNRS, University Paris- class (2005) Sud, Institut Gustave-Roussy, Villejuif, Team leader at Laboratory of France Vectorology and Gene Transfer

1989-2002 CNRS - URA 147 CNRS, University Paris- Tenured researcher CCR 1st class then Sud, Institut Gustave-Roussy (IGR), Villejuif, DR 2nd cl. (1999) France Team leader at Laboratory of Molecular Pharmacology (since1999) 1985-1989 CNRS - Laboratory of Molecular Oncology, Tenured researcher CR 1st class URA 1158, CNRS, IGR, Villejuif, France 1978-1984 CNRS - Laboratory of Basic Pharmacology Tenured researcher AR then CR 2nd cl. and Toxicology, UPR 8221 CNRS, Toulouse, (since 1983) France

6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

HONOURS:

Visiting Professor, Hebrew University of Jerusalem, Israel (2009)...... Elected fellow of the American Institute for Medical and Biological Engineering (2007) Honorary member of the Senate of the University of Ljubljana, Slovenia (2004) Visiting Professor, University of Bielefeld, Germany (2000)......

AWARDS: Prize of the Research of the Group Rhône Poulenc Rorer (1998) ...... Prize of Cancerology of the "League against the Cancer", Val de Marne, France (1996) ...... “Medical Applications of the Electricity”, Institute Electricity- Health, France (1994) ......

PROFESSIONAL SOCIETY MEMBERSHIPS: Member of the European Bioelectromagnetics Association (member of the board 2009-2012), American Institute for Biomedical Engineering (since2007), BioElectrochemical Society (member of the board and treasurer 1998-2007), Société Française du Cancer, and European Association for Cancer Research American Society for Gene Therapy (Member of the Committee on the Non-viral Gene Therapy (2003 – 2006) and of the Physical Vectorology committee (2009-2012)) Former member of the American Association for Cancer Research, European Cytokine Society, ......

OTHERS: Member of the COPé (since 1991), Operational Committee for the Ethics in the Life Sciences, Life Sciences) Department of the CNRS, the National French Agency for Scientific Research); President of the committee from 2005 to2006...... Chairman and organizer of the Gordon Research Conference on Bioelectrochemistry in 2000 Co-chairman and organizer of the XIXth International Symposium on Bioelectrochemistry and Bioenergetics, Toulouse, France, April 1-4, 2007 Coordinator of the three European projects CLINIPORATOR (2000-2003) ESOPE (2003- 2005) and ANGIOSKIN (2005-2009), member of an EU coordinated action and a EU Network of Excellence (2006-2011). Associated Editor of Bioelectrochemistry and Bioenergetics, then Bioelectrochemistry. 2000-2008,...... Guest editor for European Journal of Cancer, Journal of Membranes Biology, Comptes Rendus de l'Académie des Sciences (physique) 2006...... Co-director of the Course and International Workshop on “Electroporation based Technologies and treatments”, University of Ljubljana, (2003, 2005, 2007, 2009, 2011) th th Co-director of the 5 course ERICE5 course on Bioelectromagnetics « Medical Applications of Electromagnetic Fields: Research and Therapy » – organized by EBEA and Ettore Majorana Foundation, at Erice, Italy November 22-28, 2010 (Directors: F. Bersani, R. Cadossi and L.M. Mir) Member of the scientific committee of 28 meetings ......

SCIENTIFIC PRODUCTION: 155 articles in peer reviewed journals, 18 chapters in books 370 presentations at national and international meetings (of which 83 invited lectures at international meetings) 75 invitations to give seminars in Universities or Institutions in various countries 18 families of patent submissions.

......

7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex– maximum 5 pages) - Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions.

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT

X Balthasar van der Pol Gold Medal

X John Howard Dellinger Gold Medal

Appleton Prize

Booker Gold Medal

Issac Koga Gold Medal 9. ARGUMENTS IN SUPPORT OF THE NOMINATION Since the eighties, the activity of the candidate is focused in an area of research and thera- peutical applications which is entirely consistent with the subjects covered by the URSI commission K, namely Electromagnetics in Biology and Medicine. Doctor Lluis M. Mir has made significant contributions for the medical application of electromagnetic fields. In particular, through the development of a new technique which allows the safe and efficient treatment of solid tumors of any origin, that he termed electrochemotherapy (ECT) .The candidate conceived it, developed the concept and the tools, and he tested this new therapeutical approach in the cells in culture, then in animals models and finally in the human beings. He is still accompanying the dissemination in the clinics of this new therapy, which is already used in routine for the treatment of skin tumors and cutaneous and subcutaneous metastasis of any origin. Clinical trials are nowadays assessing the efficacyof the method to treat internal tumors such as liver metastasis, bone metastasis, deep-seated tumors, etc. Dr Mir is the leader in the field of the electrochemotherapy, from the inception to the current clinical applications. The antitumor ECT is an antitumor treatment associating electric pulsed fields and chemotherapy agents. Indeed, when cells are exposed to short and intense electric pulses, there is a transient change in the structure of the external cell membrane (usually termed cell “electroporation”) which is caused by the charges accumulation at the cell membrane level. Dr. Mir and his research team found conditions under which the electric pulses preserve the cell viability while transiently and reversibly permeabilizing the cells exposed ot the electric field. Under these conditions, Dr. Mir studied drugs as well as nucleic acids (DNA, RNA) transport across the electropermeabilized membranes. The most prominent result was achieved with bleomycin, a classical anticancer molecule reputed to be moderately effective. Indeed, the activity of this antitumor agent was shown by Mir’s group to be thousands of times higher on the electro-permeabilized cells. Then, in vivo experiments with transplanted as well as spontaneous tumors in mice resulted in the cure of the animals after a single treatment, since the first experiments. Dr Mir and colleagues also performed the first clinical trial. He continued to lead the research in this field through the coordination of EU projects, including a clinical project that defined the Standard Operating Procedures of the ECT. This clinical trial showed 74% of complete regression, and 11% more of partial regressions after a single treatment, including cases for which no other approach was feasible. ECT is now used in more than 60 cancer centres in Europe. Central among the concerns of commission K, between biology and medicine, ECT takes advantage of an artificial source of EMF to fight against the deleterious effects of cell aggressions like the UV radiations, at the opposite side of the non ionizing radiation spectrum. By promoting this technology, Dr. Mir has enabled patients suffering from cancer to benefit tangibly of the progress of science in radio- electricity. It has also the talent to communicate his knowledge to the scientific community as evidenced by his numerous international publications and communications and he is well known for his kindness as well as for his skills.

PUBLICATIONS IN PEER-REVIEWED INTERNATIONAL JOURNALS

H Factor: 42 (ISI Web of Knowledge)

10 more cited papers (NB: 1st number is the number in the candidate’s list of publications)

71. L.M. Mir, M.F. Bureau, J. Gehl, R. Rangara, D. Rouy, J.-M. Caillaud, P. Delaere, D. Branellec, B. Schwartz and D. Scherman. High efficiency gene transfer into skeletal muscle mediated by electric pulses. Proceedings of the National Academy of Sciences USA, 96, 4262-4267, 1999. 515 citations

23. L.M. Mir, S. Orlowski, J. Belehradek Jr, C. Paoletti. Electrochemotherapy: Potentiation of antitumor effect of bleomycin by local electric pulses. European Journal of Cancer, 27, 68-72 (1991). 236 citations

36. M.Belehradek, C.Domenge, B.Luboinski, S.Orlowski, J.Belehradek Jr and L.M.Mir. Electrochemotherapy, a new antitumor treatment : first clinical phase I-II trial report. Cancer, 72, 3694-3700 (1993) 194 citations

60. L.M. Mir, F.L. Glass, G.Šersa, J.Teissié, C.Domenge, D. Miklavcic, M.J. Jaroszeski, S. Orlowski, D.S. Reintgen, Z. Rudolf, M. Belehradek, R. Gilbert, M.P. Rols, J. Belehradek Jr, J.M. Bachaud, R. DeConti, B. Stabuc, P. Coninx, M. Cemazar, R.Heller. Effective treatment of cutaneous and subcutaneous malignant tumors by electrochemotherapy. British Journal of Cancer 77, 2336- 2342, 1998. 191 citations

67. Y. Bobinnec, A. Khodjakov, L.M. Mir, C.L. Rieder, B. Eddé and M. Bornens. Centriole disassembly in vivo and its effect on centrosome structure and function in vertebrate cells. Journal of Cell Biology 143, 1575-1589, 1998. 182 citations

33. S. Orlowski and L.M. Mir. Cell electropermeabilization : a new tool for biochemical and pharmacological studies. Biochimica Biophysica Acta, Reviews on biomembranes, 1154, 51-63 (1993). 173 citations

51. R. Heller, M. Jaroszeski, R. Perrott, F.Glass, C. Puleo, J. Messina, D. Rapaport, R. DeConti, N. Fenske, R. Gilbert, L.M.Mir and D. Reintgen. Phase I/II for the treatment of cutaneous and subcutaneous tumors using electrochemotherapy. Cancer 77, 964-972, 1996. 172 citations

13. L.M. Mir, H. Banoun and C. Paoletti. Introduction of definite amounts of nonpermeant molecules into living cells after electropermeabilization: direct access to the cytosol. Experimental Cell Research, 125, 15-25 (1988). 157 citations

16. S. Orlowski, J. Belehradek Jr, C. Paoletti and L.M. Mir. Transient electropermeabilization of cells in culture: increase of the cytotoxicity of anticancer drugs. Biochemical Pharmacology, 37, 4727-4733 (1988). 156 citations

37. O. Tounekti, G. Pron, J. Belehradek Jr and L.M. Mir. Bleomycin, an apoptosis-mimetic drug that induces two types of cell death depending on the number of molecules internalized. Cancer Research, 53, 5462-5469 (1993) 152 citations

Other publications quoted more than 100 times:

93. A. Gothelf, L. M. Mir and J. Gehl. Electrochemotherapy: results of cancer treatment using enhanced delivery of bleomycin by electroporation. Cancer treatment Reviews 29, 371-387, 2003. 137 citations

25. J. Belehradek Jr, S. Orlowski, B. Poddevin, C. Paoletti and L.M. Mir. Electrochemotherapy of spontaneous mammary tumours in mice. European Journal of Cancer, 27, 73-76 (1991) 119 citations

68. L.M. Mir, Michel F. Bureau, Ravi Rangara, Bertrand Schwartz and Daniel Scherman. Long-term, high level in vivo gene expression after electric pulses-mediated gene transfer into skeletal muscle - L’électrotransfert de gènes dans le muscle squelettique conduit à une expression élevée et de longue durée. Compte rendus de l'Académie des Sciences, sér III, 321, 893-899, 1998. 113 citations

27. L.M.Mir, M.Belehradek, C.Domenge, S.Orlowski, B.Poddevin, J.Belehradek Jr, G.Schwaab, B.Luboinski and C.Paoletti. L'électrochimiothérapie, un nouveau traitement antitumoral : premier essai clinique - Electrochemotherapy, a novel antitumor treatment : first clinical trial. Compte rendus de l'Académie des Sciences, sér III 313, 613-618 (1991) 111 citations

72. J. Gehl, T. H. Sorensen, K. Nielsen, P. Raskmark, S.L. Nielsen, T. Skovsgaard, and L.M. Mir. In vivo electroporation of skeletal muscle : threshold, efficacy and relation to electric field distribution. Biochimica Biophysica Acta, 1428, 233-240, 1999. 110 citations

50. C.Domenge, S.Orlowski, B.Luboinski, T. De Baere, G. Schwaab, J.Belehradek Jr and L.M.Mir. Antitumor electrochemotherapy: new advances in the clinical protocols. Cancer 77, 956-963, 1996. 110 citations

87. S. Šatkauskas, M. F. Bureau, M. Puc, A. Mahfoudi, D. Scherman, D. Miklavcic and L. M. Mir Mechanisms of in vivo DNA electrotransfer : respective contributions of cell electropermeabilization and DNA electrophoresis. Molecular Therapy, 5, 133-140, 2002. 104 citations

Other publications relevant to the electrochemotherapy

125. L.M. Mir, J. Gehl, G. Sersa, C. Collins, JR Garbay, V. Billard, P. Geertsen, Z. Rudolf, G. O’Sullivan, M. Marty. Standard Operating Procedures of the Electrochemotherapy : Instructions for the use of bleomycin or cisplatin administered either systemically or locally and electric pulses delivered by the Cliniporator™ by means of invasive or non-invasive electrodes". Eur. J. of Cancer Supplements, special issue “Electrochemotherapy”, 4, 14-25, 2006. 40 citations

126. M. Marty, G. Sersa, JR Garbay, J.Gehl, C. Collins, M. Snoj, V. Billard, P. Geertsen, J. Larkin, D. Miklavcic, I Pavlovic, S. Paulin-Kosir, M. Cemazar, N. Morsli, D. Soden, Z. Rudolf, C. Robert, G. O’Sullivan and L.M. Mir. Electrochemotherapy - a simple, highly effective and safe treatment of cutaneous and subcutaneous metastases: results of ESOPE (European Standard Operating Procedures for Electrochemotherapy) study. Eur. J. of Cancer Supplements, special issue “Electrochemotherapy”, 4, 3-13, 2006. 58 citations

69. L.M. Mir and S. Orlowski. Mechanisms of electrochemotherapy. Advanced Drug Delivery Reviews, 35, 107-118, 1999. 73 citations

39. J. Belehradek Jr, S. Orlowski, L.H. Ramirez, G. Pron, B. Poddevin and L.M. Mir. Electropermeabilization of cells in tissues assessed by the qualitative and quantitative electroloading of bleomycin. Biochimica Biophysica Acta, Biomembranes, 1190, 155-163 (1994). 97 citations

79. L.M. Mir. Therapeutic perspectives of in vivo cell electropermeabilization. Bioelectrochemistry, 53, 1-10, 2001. 73 citations

49. L.M.Mir, O. Tounekti and S.Orlowski. Bleomycin: revival of an old drug. General Pharmacology 27, 745-748, 1996. 92 citations

44. G. Sersa, M. Cemazar, D. Miklavcic and L.M. Mir. Electrochemotherapy : variable antitumor effect on different tumor models. Bioelectrochemistry and Bioenergetics, 35, 23-27 (1994) 52 citations

48. L.M.Mir, S.Orlowski, J.Belehradek Jr, J. Teissié, M. P. Rols, G. Sersa, D. Miklavcic, R. Gilbert and R. Heller. Biomedical applications of electric pulses with special emphasis on antitumor electrochemotherapy. Bioelectrochemistry and Bioenergetics, 38, 203-207, 1995. 75 citations

35. L.G. Salford, B.R.R. Persson, A. Brun, C.P. Ceberg, P.Ch. Kongstad and L.M. Mir. A new brain tumor therapy combining bleomycin with in vivo electropermeabilization. Biochemical and Biophysical Research Communications, 194, 938-943 (1993) 79 citations

57. L.M. Mir, P. Devauchelle, F. Quintin-Colonna, F. Delisle, S. Doliger, D. Fradelizi, J. Belehradek Jr and S. Orlowski. First clinical trial of electrochemotherapy for the treatment of cat soft tissue sarcomas. British Journal of Cancer 76, 1617-1622, 1997. 46 citations

61. L.H. Ramirez, S. Orlowski, D.J. An, G. Bindoula, R. Dzodic, P. Ardouin, C. Bognel, J. Belehradek Jr, J.-N. Munck and L.M. Mir. Electrochemotherapy on liver tumors in rabbits. British Journal of Cancer 77, 2104-2111, 1998. 55 citations

62. J. Gehl, T. Skovsgaard and L.M. Mir. Enhancement of cytotoxicity by electropermeabilizati-on: an improved method for screening drugs. Anti-Cancer Drugs 9, 319-325, 1998. 45 citations

47. O. Tounekti, J. Belehradek Jr and L.M. Mir. Relationships between DNA fragmentation, chromatin condensation and changes in flow cytometry profiles detected during apoptosis. Experimental Cell Research, 217, 506-517, 1995. 72 citations

112. R.V. Davalos, L.M. Mir and B. Rubinsky. Tissue ablation with irreversible electroporation. Annals of Biomedical Engineering, 33, 223-231, 2005. 57 citations

86. J. Gehl, T. Skovsgaard and L.M. Mir Vascular reactions to in vivo electroporation : Characterization and consequences for drug and gene delivery. Biochim. Biophys. Acta, 1569, 51-58, 2002. 58 citations

46. L.M.Mir, C. Roth, S.Orlowski, F. Quintin-Colonna, D. Fradelizi, J.Belehradek Jr and P. Kourilsky. Systemic antitumor effects of electrochemotherapy combined with histoincompatible cells secreting interleukin-2. Journal of Immunotherapy, 17, 30-38, 1995. 59 citations

81. O. Tounekti, A. Kenani, N. Foray, S. Orlowski and L.M. Mir. The ratio of single- to double-strand DNA breaks and their absolute values determine cell death pathway. British Journal of Cancer, 84, 1272-1279, 2001. 40 citations

26. B. Poddevin, S. Orlowski, J. Belehradek Jr and L.M. Mir. Very high cytotoxicity of bleomycin introduced into the cytosol of cells in culture. Biochemical Pharmacology, 42(S), 67-75 (1991). 35 citations

73. J. Gehl and L.M. Mir. Determination of optimal parameters for in vivo gene transfer by electroporation, using a rapid in vivo test for cell electropermeabilization. Biochemical and Biophysical Research Communications, 261, 377-380, 1999. 67 citations

77. D. Miklavcic, D. Šemrov, H. Mekid and L. M. Mir. A validated model of in vivo electric field distribution in tissues for electrochemotherapy and for DNA electrotransfer for gene therapy. Biochimica Biophysica Acta, 1519, 73-83, 2000. 81 citations

65. Y. Kubota, L.M. Mir, T. Nakada, I. Sasagawa, H. Suzuki and N. Aoyama. Successful treatment of metastatic skin lesions from bladder cancer by electrochemotherapy. Journal of Urology 160, 1426, 1998. 24 citations

91. G. Pucihar, L. M. Mir and D. Miklavčič. The effect of pulse repetition frequency on Lucifer Yellow uptake by means of cell electropermeabilization in vitro with possible applications in electrochemotherapy. Bioelectrochemistry, 57, 167-172, 2002. 27 citations

138 S. Čorović, B. Al Sakere, V. Haddad, D. Miklavčič and L. M. Mir. Importance of contact surface between electrodes and treated tissue in electrochemoterapy. Technology in Cancer Research and Treatment, 7, 393-400, Oct 2008; 7 citations 144 J. Villemejane and L.M Mir. Physical methods of nucleic acids transfer – General concepts and applications. British Journal of Pharmacology, 157, 207-219, May 2009. 5 citations 141 A. Ivorra, B. Al-Sakere, B. Rubinsky and L. M. Mir. Use of conductive gels for electric field homogenization increases the antitumor efficacy of electroporation therapies. Phys. Med. Biol. 53, 6605-6618, Nov 2008 4 citations 147 A. Ivorra, B. Al-Sakere, B. Rubinsky and L.M. Mir. In vivo electrical conductivity measurements during and after electroporation of sarcomas: conductivity changes reflect treatment outcome. Phys. Med. Biol. 54:5949-63, Oct 2009. 4 citations

SELECTION OF PUBLICATIONS IN BOOKS

1. L.M. Mir, S. Orlowski, J. Belehradek Jr, B. Poddevin, G. Pron, C. Domenge, M. Belehradek, B. Luboinski and C. Paoletti. Electrochemotherapy, a new antitumor treatment using local electric pulses. in : Electricity and Magnetism in Biology and Medicine, M. Blank, Ed., San Francisco Press, Inc., San Francisco, California, USA, (1993) pages 119-121.

3. L.M. Mir. Biomedical applications of short, intense electric pulses. in: Electricity and Magnetism in Bioloy and Medecine, F. Bersani, Ed. Plenum Publishing Corporation, New York, (1999) pages 33- 36.

4. L.M. Mir and S. Orlowski. The basis of electrochemotherapy. in: "Electrically mediated delivery of molecules to cells - electrochemotherapy, electrogenetherapy, and transdermal delivery by electroporation", M. Jaroszeski, R. Heller and R. Gilbert, eds., Methods in Molecular Medicine, volume 37, Humana Press, Totowa, New Jersey, (2000) pages 99-117.

5. S.Orlowski and L.M. Mir. Treatment of murine transplanted subcutaneous tumors using systemic drug injection. in: "Electrically mediated delivery of molecules to cells - electrochemotherapy, electrogenetherapy, and transdermal delivery by electroporation", M. Jaroszeski, R. Heller and R. Gilbert, eds., Methods in Molecular Medicine, volume 37, Humana Press, Totowa, New Jersey, (2000) pages 247-252.

11. L. M. Mir, P. H. Moller, F. André and J. Gehl. Electric pulses mediated gene delivery to various animal tissues. In: “Non-Viral Vectors For Gene Therapy”, 2nd Edition – part II, L. Huang, M.-C. Hung, E.Wagner, eds., Advances in Genetics vol 54, (2005) pages 83-114.

12. L. M. Mir in the name of the CLINIPORATOR and ESOPE consortia. Electrogenetransfer in clinical applications. In: DNA Pharmaceuticals: Formulation and Delivery in Gene Therapy, DNA Vaccination and Immunotherapy, M. Schleef, ed., Wiley-VCH Verlag GmbH&Co, KgaA, Weinheim, (2005) pages 219-226.

13. L. M. Mir. Application of Electroporation gene therapy: past, current, and future. In: “Electroporation Protocols: Experimental and Clinical Medicine”, S. Li, ed, Methods in Molecular Biology, volume 423, Humana Press, Totowa, New Jersey, (2008) pp 3-17.

14. L. M. Mir. The place of the electroporation-based antitumor therapies in the electrical armamentarium against cancer. In: Irreversible electroporation, B Rubinsky editor, pp. 223–233. Springer-Verlag Berlin Heidelberg, (2010)

15. G. Sersa, J. Gehl, J-R. Garbay, D. Soden, G. O’Sullivan, L. W. Matthiessen, M. Snoj and L. M. Mir. Electrochemotherapy of small tumors; experience from the European Standard Operating Procedures for Electrochemotherapy (ESOPE) group. In “Electroporation in Science and Medicine”, Stephen Kee, Edward Lee and Julie Gehl Eds, Springer, New York, (2010).

16. A. Silve and L. M. Mir. Cell electropermeabilisation and small molecules cellular uptake: the electrochemotherapy concept. In “Electroporation in Science and Medicine”, Stephen Kee, Edward Lee and Julie Gehl Eds, Springer, New York, (2010).

17. A. Silve, J. Villemejane, V. Joubert, A. Ivorra and L. M. Mir. Nanosecond pulsed electric field delivery to biological samples : difficulties and potential solutions. In “Advanced Electroporation Techniques in Biology and Medicine”, M. Markov, D. Miklavcic and A. Pakhomov Eds, CRC Press, Taylor & Francis Group, pp. 353-368, (2010).

SELECTION OF PATENTS

United States Patent number 5,468,223; title : Electrochemotherapy; date Nov.21, 1995; inventor : Lluis MIR; assignee: CNRS.

United States Patent number 5,674,267; title : Electric pulse applicator using pairs of needle electrodes for the treatment of biological tissues; date Oct.7, 1997; inventors Lluis M. MIR and S. ORLOWSKI; assignee : CNRS.

US provisional No 60/083,858, Filing date : May 1, 1998; title: Apparatus for optimized electrotransfer of nucleic acid vectors to tissues in vivo; inventors: Michel BUREAU, Lluis M. MIR, Daniel SCHERMAN and Bertrand SCHWARTZ. Extensions: PCT/EP98/03976 and WO990117

TO01A000534, title: Electroporation device which reduces muscle contraction and pain sensation. Filing date June 4, 2001. Extension: PCT/IT02/00361 dated June 4, 2002. International public-cation number WO 02/098504 publication date 12/12/02 - Inventors: D. Miklavcic; LM Mir

European patent application n° 1274830, title: Device for electroporation under continuous control of cell permeabilization” - International publication number WO 2001/081532 publication date 01/11/01 – Inventors: D. Miklavcic; LM Mir, E. Neumann, B. Persson, issued on 03/01/05.

TO2002A000477, title: “Electroporation device" Extension: PCT/EPO03/05993 dated 10 June 2003. International publication number WO 03/104448 publication date 18/12/03 – Inventors: D. Miklavcic; LM Mir. Filed in the USA on 25/08/05 with the application n° 10/517.038.

European patent application n° EP 05291825.7, title « Combination of electric pulses for DNA electrotransfer » dated 2 septembre 2005. Extensions PCT/IB2006/002401 and US provisional n°60/713.623 03 – Inventors:; LM Mir, D. Miklavcic.

Appendix 2 – page 1

1. NAME OF CANDIDATE: PARABONI ALDO ...... Last, First, Middle

PRESENT OCCUPATION: UNIVERSITY FULL PROFESSOR ......

Position, Organization CHAIR OF ANTENNAS AND PROPAGATION BY THE POLITECNICO DI MILANO ......

BUSINESS ADDRESS: ...... POLITECNICO DI MILANO, DIPARTIMENTO DI ELETTRONICA E INFORMAZIONE, PIAZZA L. DA VINCI 32, 20133 MILANO, ITALY ......

HOME ADDRESS: VIA TADINO 25, 20124 MILANO (ITALY) ......

BIRTHDATE: 17 MARCH 1940, NATIONALITY: ITALIAN: SEX: MALE - female (Underline the appropriate)

2. EDUCATION (Honorary degrees denoted by H) Educational Institution Location Degrees Year DEGREE IN ELECTRONIC MILANO 1964 ENGINEERING BY THE POLITECNICO DI MILANO ......

3. PROPOSED CITATION (not more than thirty words) LIFE-LONG THEORETICAL AND EXPERIMENTAL ACHIEVEMENTS IN THE FIELD OF CENTIMETER AND MILLIMETER WAVE PROPAGATION ALONG SLANT PATHS. HE WAS THE KEY RESPONSIBLE PERSON FOR THE EXPERIMENTS: SIRIO, ITALSAT AND OLYMPUS(FOR ITALY)......

4. NOMINATOR:

PROF. DR. MADHU CHANDRA DEKAN FAKULTÄT FÜR ELEKTROTECHNIK UND INFORMATIONSTECHNIK LEITER DER PROFESSUR FÜR HOCHFREQUENZTECHNIK UND PHOTONIK TECHNISCHE UNIVERSITÄT CHEMNITZ

ADDRESS: REICHENHAINER STRASSE 70 D-09126 CHEMNITZ, GERMANY ...... PHONE: 0049 371 531 24340 ...... FAX: 0049 371 531 24349 ...... E-MAIL : [email protected] ......

Appendix 2 – page 2 5. PROFESSIONAL HISTORY - Present position first. Limit copy to this page.

From (year) to (year) Name of Company/Institution Position and Responsibilities

1965 1968 Politecnico di Milano Researcher

1968 1981 Politecnico di Milano Associate professor

1981 2010 Politecnico di Milano Full professor (Chair of Antennas and Propagation) ......

1971 1982 Italian National Research Council Responsible for the cm and mm propagation experimental activity conducted with the satellite SIRIO (11-18 GHz bands)

Coordinator of the international participation to the SIRIO experiment

1982 1991 Italian Space Agency (ASI) Project manager of the ITALSAT propagation experiment (40-50 GHz).

1991 1999 Italian Space Agency Coordinator of the national and international participation to the ITALSAT propagation experiment

2000 2010 Italian Space Agency Preparation of the new

ALPHASAT-TDP5 satellite propagation experiment in the 20-40 GHz bands

Coordinator of the national and international participation to the ALPHASAT propagation experiment in the role of principal investigator

......

......

......

......

......

......

Appendix 2 – page 3

6. HONOURS, AWARDS, PROFESSIONAL SOCIETY MEMBERSHIPS, MAJOR PROFESSIONAL GOVERNMENT OR INTERNATIONAL COMMITTEE MEMBERSHIPS

1990 Piero Fanti International prize released by INTELSAT/TELESPAZIO for activity in satellite technology innovation

1995 International Prize Cristoforo Colombo for Space Communications (Gold medal appointed by the “Istituto Internazionale per le Telecomunicazioni” (City of Genova) ...... 1980 - 2008 Member of various COST projects (205, 255,280) of the EEC ......

7. PRINCIPAL PUBLICATIONS, PATENTS (Give list in annex – maximum 5 pages)

- Prefer items of sole responsibility, otherwise give joint names. - Mention only books and articles in referred international journals. - Identify the ten most significant contributions.

8. PRIZE OR MEDAL FOR WHICH THE NOMINEE'S WORK IS PARTICULARLY RELEVANT

X Balthasar van der Pol Gold Medal

X John Howard Dellinger Gold Medal

Appleton Prize

X Booker Gold Medal

Issac Koga Gold Medal

Appendix 2 – page 4 9. ARGUMENTS IN SUPPORT OF THE NOMINATION (Limit to this page)

Since the beginning of his professional life, Prof. Paraboni participated in the design, development and conduction of significant experiments, among the first ones for their time, that helped to understand the main phenomena governing the propagation of Centimetre and Millimetre waves along slant paths (largely unknown at that time). The first of these experiments was conducted with the Italian satellite SIRIO and allowed testing and understanding the propagation phenomena in the ku and ka frequency bands (11 to 18 GHz). This pioneering experiment (along with similar ones in the US and Japan) opened the way to the implementation and verification of the first prediction methods and to the comprehension of other physical phenomena necessary for the design of future space TLC systems. SIRIO was followed by the Italian propagation experiment ITALSAT, again realized under the supervision of Prof. Paraboni, which put at disposal of the world community the first data in the Q/V bands (40 and 50 GHz) ever collected (a very large data base indeed, unique until today). In parallel, Prof. Paraboni fostered the participation of Italy to the OLYMPUS propagation experiment (12, 20 and 30 GHz) and encouraged the most important Italian research administrations to realize the three biggest terminals in Europe. The ITALSAT data, and the OLYMPUS ones collected in Italy, were analyzed by the Politecnico di Milano under the guidance of Professor Paraboni and the results were made available to the world scientific community thereby stimulating an intense modelling and testing activity in many research centres worldwide. More recently, Prof. Paraboni proposed the realization of a pair of satellite propagation experiments in the Ka and Q bands (20 and 40 GHz). The first one, called DAVID, could not arrive at a conclusion due to intervening hindrances in Italy; the second one, called ALPHASAT-TDP5, will instead see the light in 2013; again a large synergy and cooperation between European experimenters is expected similarly to what happened with the other experiments mentioned above. Beside this intense experimental activity, Prof. Paraboni, along with his group of very qualified researchers, brought ahead a significant theoretical activity, mainly based on the measurements collected within the cited experiments. Among the most significant results, we cite here the ones in the field of depolarization, fade correlation across separated locations (space correlation), frequency scaling, scintillations, topology of the rain cells; many other results, not recalled here for brevity, are indicated in the annexed bibliography. In conclusion, we note that Prof. Paraboni was one of the key and forceful promoters of highly acclaimed cooperative partnerships within the world community of propagation experimenters based on the exchange of data, ideas and co-participation in numerous research contracts. There is a strong consensus of opinion that the contributions of Prof. Parboni have already made a significant mark in the evolution of propagation science.