Curriculum Vitae - Shanhui Fan Address
Curriculum Vitae - Shanhui FanAddressSpilker Building of Applied Science and Engineering, Room 314Ginzton LaboratoryStanford University, Stanford, CA 94305Email: shanhui@stanford.edu; Tel: (650)724-4759Education Massachusetts Institute of Technology, Ph. D in Physics, 1997.University of Science and Technology of China, undergraduate, 1988-92.Employment Stanford University The Joseph and Hon Mai Goodman Professor of the School of Engineering, 2021– present. Professor of Applied Physics (by courtesy), 2014 – present. Senior Fellow, Precourt Institute for Energy, 2018 – present. Director, Edward L. Ginzton Laboratory, 2014 – 2021. Professor of Electrical Engineering, 2012 – 2021. Associate Professor of Electrical Engineering, 2007 – 2012. Assistant Professor of Electrical Engineering, 2001 – 2007.University of Sydney, Australia Visiting Professor of Physics, Jan. 2012-Jul. 2012.Massachusetts Institute of Technology Research Scientist, Research Laboratory of Electronics, 1999-2001. Postdoctoral Research Associate, Department of Physics, 1997-1999.Industry Experience Co-Founder, SkyCool Systems, a company aiming to commercialize radiative coolingtechnology.Co-Founder, FlexCompute Inc., a company aiming to commercialize cloud-basedhigh-throughput scientific computing.Stryker, Consultant, 2021-present.Toyota, Consultant, 2011-present.OptoResearch Inc, Consultant, 2006.Clarendon Photonics, Member of the Technology Advisory Board, 2001-2004Clarendon Photonics, Consultant, 1999-20011
Honors and Awards Simons Investigator in Physics, 2021.Vannevar Bush Faculty Fellowship from the U. S. Department of Defense, 2017.Thomson Reuters Highly Cited Researcher in Physics, since 2015.Fellow, IEEE, 2010. For “contributions to nanophotonics”.Fellow, SPIE, 2009.Fellow, the American Physical Society, 2008. For “contributions to the theory andapplications of nanophotonic structures and devices, including photonic crystals,plasmonics and meta-materials.”Fellow, the Optical Society of America, 2007. “For many deep and creativecontributions to physics, analysis, and novel devices in semiconductor, dielectric andmetallic optical nanostructures”.The Adolph Lomb Medal from the Optical Society of America, 2007. “Forfundamental work in nano-photonic structures”.The U. S. National Academy of Sciences Award for Initiative in Research, 2007.“For innovative research on the theory and applications of photonic crystal devices”.STMicroelectronics Faculty Scholar Award, Stanford University, 2007-2011.David and Lucile Packard Fellowship in Science and Engineering, 2003.National Science Foundation Faculty Early Career Development Award, 20023M Pre-tenured Faculty Award, 2002Robert N. Noyce Faculty Award, Stanford University, 2001Professional Activities Advisory Board and Visiting Committees Member of External Advisory Board, The NSF Material Research Science andEngineering Center (MRSEC), University of Utah, 2013-2016. External Visiting Committee, Department of Electrical and ComputerEngineering, Boston University, 2021-present.Editorial Activities Editorial Advisory Board, Photonics and Nanostructures: Fundamentals andApplications, 2005-present. Associate Editor, Applied Physics Letters, 09/2013-04/2019. Editorial Board, Advanced Optical Materials, 2019-present Editorial Advisory Board, Nanophotonics, 2019-present. Guest Editor, Special Issue on Photovoltaic Energy Conversion, Physical ReviewApplied, 2021.Conference Co-Chair or Co-Organizer Co-Chair, Nanophotonics Symposium, the Material Research Society FallMeeting, Boston, 2002. (with Mark Brongersma)2
Co-Chair, MRS workshop on three-dimensional multifunctional ceramiccomposite, 2005. (with Paul Braun). Co-Chair, Symposium on plasmonics, the Material Research Society FallMeeting, Boston 2005. (with Mark Brongersma) Co-Organizers, Photonics Design, Technology, and Packaging II, SPIE SmartMaterials, Nano and Micro-Systems, 2006. (with Derek Abbott, Yuri Kivshar,and Halian H. Rubinsztein-Dunlop.) Program Chair: OSA Topical Meeting on Solar Energy: New Materials andNanostructured Devices for High Efficiency, Stanford University, Stanford, CA,June 2008. Program Committee Co-Chair, OSA Topical Meeting on Optical Nanostructuresfor Photovoltaics, 2010. Co-chair, MRS Symposium on Photonic and Plasmonic Materials for EnhancedPhotovoltaic Performance, MRS Fall Meeting, Boston, MA. December 2011. Organizer, Symposium on Optics and Alternative Energy, OSA Annual Meeting,Rochester, NY, October 2012.Conference Technical Committee Member Nanophotonics for Communications: Materials, Devices and Systems, SPIEOptics East, 2004. Nanophotonics for Communications: Materials, Devices and Systems II, SPIEOptics East, 2005. Nanophotonics for Communications: Materials, Devices and Systems III, SPIEOptics East, 2006. Tuning the Optic Response of Photonic Bandgap Structures III, SPIE AnnualMeeting, 2006. Program Subcommittee on Fundamentals of Meta-materials, Periodic andRandom Media, QELS, 2006. Photonic Crystal Materials and Devices IV, SPIE Photonics West, 2006. Nanophotonics for Communications: Materials, Devices and Systems IV, SPIEOptics East, 2007. Active Photonic Crystals, SPIE Annual Meeting, 2007. Slow and Fast Light (SL), OSA Topical Meeting, Salt Lake City, Utah, July 2007. Photonic Crystal Materials and Devices VI, SPIE Photonics West, 2007. The 7th Pacific Rim Conference on Lasers and Electro-Optics, 2007. International Symposium on Photonic and Electromagnetic Crystal Structures(PECS VII), 2007. Active Photonic Crystals II, SPIE Annual Meeting, 2008. Photonic Crystal Materials and Devices VII, SPIE Photonics West, 2008. Advances in Slow and Fast Light II, SPIE Photonics West, 2009. Optics and Photonics for Advanced Energy Technology, OSA Topical Meeting,2009. 3
Photonic and Phononic Crystal Materials and Devices VIII, SPIE Photonics West,2009.The 53rd International Conference on Electron, Ion and Photon Beam Technologyand Nanofabrication (EIPBN), 2009.Physics and Simulation of Optoelectronic Devices XVIII, SPIE PhotonicsPhotonics West, 2010.Advances in Slow and Fast Light III, SPIE Photonics West, 2010.Photonic and Phononic Crystal Materials and Devices IX, SPIE Photonics West,2010.Subcommittee on Micro and Nanophotonic Devices, Conference on Lasers andElectro-Optics (CLEO), 2010.The 54th International Conference on Electron, Ion and Photon Beam Technologyand Nanofabrication (EIPBN), 2010.Active Photonic Materials III, SPIE Annual Meeting, 2010.Photonic and Phononic Properties of Engineered Nanostructures, SPIE PhotonicsWest, 2011.Advances in Slow and Fast Light IV, SPIE Photonics West, 2011.Physics and Simulation of Optoelectronic Devices XIX, SPIE Photonics West,2011.Active Photonics Materials IV, SPIE Annual Meeting, 2011.Physics and Simulations of Optoelectronic Devices XX, SPIE Photonics West,2012.Photonic and Phononic Properties of Engineered Nanostructures II, SPIEPhotonics West 2012.Advances in Slow and Fast Light V, SPIE Photonics West, 2012.Advances in Slow and Fast Light VI, SPIE Photonics West, 2013.Photonic and Phononic Properties of Engineered Nanostructures III, SPIEPhotonics West 2013.Nanophotonic Device and Applications, Integrated Photonic Research (IPR)2013.Active Photonics Materials V, SPIE Optics Photonics, 2013.Smart Photonic and Optoelectronic Integrated Circuits I, SPIE Photonics West,2014.Advances in Slow and Fast Light VII, SPIE Photonics West 2014.Active Photonic Materials VI, SPIE Optics Photonics, 2014.Smart Photonic and Optoelectronic Integrated Circuits XVII, SPIE PhotonicsWest, 2015.Slow Light, Fast Light, and Opto-Atomic Precision Metrology VIII, SPIEPhotonics West, 2015.Active Photonic Materials VII, SPIE Optics Photonics, 2015.4
International Advisory Committee, PECS-XII, the 12th International Symposiumon Photonic and Electromagnetic Crystal Structures, 2016. Active Photonic Platforms VII, SPIE Optics Photonics, 2017. OE111: Smart Photonic and Optoelectronic Integrated Circuits XX, SPIEPhotonics West, 2018. OP103: Active Photonic Platforms X, SPIE Optics Photonics, 2018. OE111: Smart Photonic and Optoelectronic Integrated Circuits XXI, SPIEPhotonics West, 2019. Active Photonic Platforms XI, SPIE Nanoscience Engineering, 2019. Smart Photonic and Optoelectronic Integrated Circuits XXI, SPIE Opto 2019. Active Photonic Platforms XII, SPIE Nanoscience Engineering, 2020. Metamaterials XIII, SPIE Optics Optoelectronics, 2021. Active Photonic Platforms XIII, SPIE Nanoscience Engineering, 2021. Steering Committee Member, International Conference on Photonics andAdvanced Intelligent Systems, December 11, 2021.Award Committee Member of Award Committee for the Rolf Landauer Medal, ETOPIM, 20132015. Patents1.S. Fan, P. R. Villeneuve, R. D. Meade, and J. D. Joannopoulos, “Three dimensionalperiodic dielectric structures having photonic bandgaps”, U. S. Patent 5,440,421(Issued on August 8, 1995).2.S. Fan, P. R. Villeneuve, R. D. Meade, and J. D. Joannopoulos, “Three dimensionalperiodic dielectric structures having photonic bandgaps”, U. S. Patent 5,600,483(Issued on February 7, 1997).3.J. D. Joannopoulos, S. Fan, P. R. Villeneuve, and R. D. Meade, “Resonantmicrocavities employing one-Dimensional periodic dielectric waveguides”, U. S.Patent 5,682,401 (Issued on October 28, 1997).4.J. D. Joannopoulos, S. Fan, P. R. Villeneuve and E. F. Schubert, “Light emittingdevice utilizing a periodic dielectric structure”, U. S. Patent 5,995,749 (Issued onSeptember 21, 1999).5.E. R. Brown, O. B. McMahon, S. Fan, P. R. Villeneuve and J. D. Joannopoulos,“Metallodielectric photonic crystal”, U. S. Patent 5,990,850 (Issued on November23, 1999).6.J. D. Joannopoulos, P. R. Villeneuve, D. S. Abrams and S. Fan, “Tunablemicrocavity and methods of using nonlinear materials in a photonic crystal”, U. S.Patent 6,058,127 (Issued on May 02, 2000).5
7.S. Fan, P. R. Villeneuve, J. D. Joannopoulos, H. A. Haus and B. E. Little, “Highefficiency channel drop filter with absorption induced on/off switch andmodulation”, U. S. Patent 6,101,300 (Issued on August 8, 2000).8.P. R. Villeneuve, S. Fan, J. D. Joannopoulos and H. A. Haus, “High efficiencychannel drop filter”, U. S. Patent 6,130,969 (Issued on October 10, 2000).9.J. D. Joannopoulos, S. Fan, J. N. Winn and Y. Fink, “High omnidirectionalreflector”, U. S. Patent 6,130,780 (Issued on October 10, 2000).10.S. G. Johnson, S. Fan, P. R. Villeneuve, L. Kolodziejski and J. D. Joannopoulos,“Composite photonic crystals” U. S. Patent 6,134,043 (Issued on October 17,2000).11.S. G. Johnson, S. Fan, P. R. Villeneuve, C. Manolatou, H. A. Haus and J. D.Joannopoulos, “Optical waveguide crossings” U. S. Patent 6,198,860 (Issued onMarch 6, 2001).12.P. R Villeneuve, S. Fan, G. S. Petrich, L. A. Kolodziejski, and J. D. Joannopoulos,“Tunable add/drop filter using side-coupled resonant tunneling”, U. S. Patent6,424,763 (Issued on July 23, 2002).13.Y. Fink, S. Fan, E. Thomas, C. Chen and J. D. Joannopoulos, “Omnidirectionalmultilayer device for enhanced optical waveguiding”, U. S. Patent 6,463,200(Issued on October 8, 2002).14.S. Fan, P. R. Villeneuve, and J. D. Joannopoulos, “Resonant-tunneling electronictransportors”, U. S. Patent 6,512,242 (Issued on January 28, 2003).15.S. Fan, P. R. Villeneuve, J. D. Joannopoulos, B. E. Little, and H. A. Haus,“Absorption induced on/off switching and modulation”, U. S. Patent 6,512,866(Issued on January 28, 2003).16.A. Erchak, S. Fan, E. P. Ippen, J. D. Joannopoulos, G. S. Petrich, and D. J. Ripin,“Input light coupler using a dielectric contrast distributed in at least twodimensions”, U. S. Patent 6,574,383 (Issued on June 3, 2003).17.Y. Fink, S. Fan, E. Thomas, C. Chen and J. D. Joannopoulos, “Omnidirectionalmultilayer device for enhanced optical waveguiding”, U. S. Patent 6,603,911(Issued on August 5, 2003).18.S. Fan, J. D. Joannopoulos, G. B. Kenny, M. Lipson, K. M. Chen, and L. C.Kimerling, “Thin film filters using omndirectional reflectors”, U. S. Patent6,624,945 (Issued on September 23, 2003).19.S. Fan, “Creating Sharp Asymmetric Lineshapes in Microcavity Structures,” U. S.Patent 6,819,691 (Issued on November 16, 2004).20.A. Mekis, S. Fan, J. D. Joannopoulos, and P. R. Villeneuve, “Low-loss resonatorand method of making same,” U. S. Patent 6,853,789 (Issued on February 8, 2005).21.J. D. Joannopoulos, S. Fan, J. N. Winn, and Y. Fink, “High omnidirectionalreflectors,” U. S. Patent 6,903,873 (Issued on June 7, 2005).6
22.M. Ibanescu, J. D. Joannopoulos, Y. Fink, S. G. Johnson, and S. Fan, “Dielectricwaveguide with transverse index variation that support a zero group velocity modeat a non-zero longitudinal wavevector,” U. S. Patent 6,909,729 (Issued on June 21,2005).23.M. Soljacic, S. Fan, M. Ibanescu, S. G. Johnson, and J. D. Joannopoulos, “MachZehnder interferometer using photonic band gap crystals,” U. S. Patent 6,917,431(Issued on July 12, 2005).24.W. Lau and S. Fan, “Creating Large Bandwidth Line Defects by EmbeddingDielectric Waveguides Into Photonic Crystal Slabs,” U. S. Patent 6,957,003 (Issuedon October 18, 2005).25.H. K. Kim, S. Fan, G. S. Kino, J. Shin and M. J. F. Digonnet, “Method ForConfiguring Air-Core Photonic Bandgap Fibers Free of Surface Modes”, U. S.Patent 7,110,650 (Issued on September 19, 2006).26.M. F. Yanik, W. Suh, Z. Wang, and S. Fan, “Stopping and time reversing light in awaveguide with an all-optical system”, U. S. Patent 7,116,864 (Issued on October3, 2006).27.W. Suh, O. Solgaard and S. Fan, “Guided resonance dielectric filter system”, U. S.Patent 7,142,364 (Issued on November 28, 2006).28.W. Suh, M. F. Yanik, O. Solgaard and S. Fan, “Photonic crystal reflectors/filtersand displacement sensing applications”, U. S. Patent 7,155,087 (Issued onDecember 26, 2006).29.J. D. Joannopoulos, S. Fan, M. Lipson, K. M. Chen, and L. C. Kimerling, “Tunablechromatic dispersion compensation”, U. S. Patent 7,190,853 (Issued on March 13,2007).30.H. K. Kim, S. Fan, G. S. Kino, J. Shin, M. J. F. Digonnet, and V. Dangui, “Photonicbandgap fiber with a core ring”, U. S. Patent 7,228,041 (Issued on June 5, 2007).31.A. Solomon, R. E. Bryant, A. A. Erchak, S. Fan, E. P. Ippen, J. D. Joannopoulos,S. G. Johnson, L. A. Kolodziejski, E. Lidorikis, G. S. Petrich, and M. L. Povinelli,“Nano-electromechanical high-index contrast”, U. S. Patent 7,260,287 (Issued onAugust 21, 2007).32.M. F. Yanik and S. Fan, “Ultra-slow down and storage of light pulses, and alteringof pulse spectrum”, U. S. Patent 7,269,313 (Issued on September 11, 2007).33.J. M. Kahn, M. A. Horowitz, O. Solgaard, and S. Fan, “Adaptive optical signalprocessing with multimode waveguides”, U. S. Patent 7,327,914 (Issued onFebruary 5, 2008).34.H. K. Kim, S. Fan, G. S. Kino, J. Shin, M. J. F. Digonnet, V. Dangui, “Photonicband gap fiber with a core ring”, U. S. Patent 7,400,806 (Issued on July 15, 2008).35.W. Suh, M. F. Yanik, O. Solgaard, and S. Fan, “Photonic crystal reflectors/filtersand displacement sensing applications”, U. S. Patent 7,412,127 (Issued on August12, 2008).7
36.P. B. Catrysse, H. Shin and S. Fan, “Effect of the plasmonic dispersion relation onthe transmission properties of sub-wavelength holes”, U. S. Patent 7,417,219(Issued on August 26, 2008).37.M. A. Terrel, M. J. F. Digonnet, and S. Fan, “Polarization controller using a hollowcore photonic band gap fiber”, U. S. Patent 7,430,345 (Issued on September 30,2008).38.H. K. Kim, S. Fan, G. S. Kino, J. Shin, M. J. F. Digonnet, and V. Dangui, “Opticalfiber with a core ring”, U. S. Patent 7,489,848 (Issued on February 10, 2009).39.J. M. Kahn, M. Horowitz, O. Solgaard, and S. Fan, “Adaptive optical signalprocessing with multi-mode waveguides”, U. S. Patent 7,509,002 (Issued on March24, 2009).40.M. A. Terrel, M. J. F. Digonnet, and S. Fan, “Optical device using a hollow-corephotonic bandgap fiber”, U. S. Patent 7,620,283 (Issued on November 17, 2009).41.J. M. Kahn, M. A. Horowitz, O. Solgaard, and S. Fan, “Adaptive optical signalprocessing with multimode waveguides”, U. S. Patent 7,844,144 (Issued onNovember 30, 2010).42.M. A. Terrel, M. J. F. Digonnet, and S. Fan, “System and method for using slowlight in optical sensors”, U. S. Patent 7,911,622 (Issued on March 22, 2011).43.M. A. Terrel, M. J. F. Digonnet, and S. Fan, “Unidirectional crow gyroscope”, U.S. Patent 8,068,232 (Issued on November 29, 2011).44.M. J. F. Digonnet, S. Fan, and S. Lloyd, “Laser-driven optical gyroscope having anon-negligible source coherence length”, U. S. Patent 8,223,340 (Issued on July 17,2012).45.M. A. Terrel, M. J. F. Digonnet, and S. Fan, “System and method for slow light inoptical sensors”, U. S. Patent 8,300,231 (Issued on October 30, 2012).46.Y. Cui, J. Zhu, C. –M. Hsu, S. Connor, Z. Yu, S. Fan, G. Burkhard, “Substratecomprising a nanometer-scale projection array”, U. S. Patent 8,318,604 (Issued onNovember 27, 2012).47.H. K. Kim, S. Fan, G. S. Kino, J. Shin, and M. J. F. Digonnet, “Optical Fiber”, U.S. Patent 8,428,412 (Issued on April 23, 2013).48.M. J. F. Digonnet, S. Fan and S. Lloyd, “Optical sensor having a non-negligiblesource coherence length”, U. S. Patent 8,437,005 (Issued on May 7, 2013).49.Z. Yu and S. Fan, “Optical isolation created by indirect interband photonictransition”, U. S. Patent 8,639,064 (Issued on January 28, 2014).50.M. J. F. Digonnet, S. Fan, and S. Lloyd, “Optical sensor having a non-negligiblesource coherence length”, U. S. Patent 8,681,339 (Issued on March 25, 2014).51.M. A. Terrel, M. J. F. Digonnet, and S. Fan, “Method of using a unidirectional crowgyroscope”, U. S. Patent 8,705,044 (Issued on April 22, 2014).8
52.M. J. F. Digonnet, S. Fan, H. Wen, and M. Terrel, “Slow-light fiber Bragg gratingsensor”, U. S. Patent 8,797,540 (Issued on August 5, 2014).53.Y. Cui, J. Zhu, C. –M. Hsu, S. Fan, and Z. Yu, “Optoelectronic semiconductordevice and method of fabrication”, U. S. Patent 8,896,077 (Issued on November25, 2014).54.M. Terrel, M. J. F. Digonnet, and S. Fan, “Optical device using a hollow-corephotonic-bandgap fiber”, U. S. Patent 8,965,164 (Issued on February 24, 2015).55.M. J. F. Digonnet, S. Fan, H. Wen, and M. A. Terrel, “Optical device with fiberBragg grating and narrowband optical source”, U. S. Patent 9,019,482 (Issued onApril 28, 2015).56.H. Wen, M. J. F. Digonnet, and S. Fan, “System and method for measuringperturbations using a slow-light fiber Bragg grating sensor”, U. S. Patent 9,025,157(Issued on May 5, 2015).57.X. Yu, S. Sandhu, S. Beiker, R. E. Sassoon, S. Fan, “Wireless energy transfer”, U.S. Patent 9,142,998 (Issued on September 22, 2015).58.M. J. F. Digonnet, S. Fan, H. Wen, and M. A. Terrel, “Optical device utilizing fiberBragg grating and narrowband light with non-Bragg wavelength”, U. S. Patent9,329,089 (Issued on May 3, 2016).59.H. Wen, M. J. F. Digonnet, and S. Fan, “System and method for measuringperturbations utilizing an optical filter and a narrowband optical source”, U. S.Patent 9,347,826 (Issued on May 24, 2016).60.M. J. F. Digonnet, S. Fan, H. Wen, and M. A. Terrel, “Slow-light sensor utilizingan optical filter and a narrowband optical source”, U. S. Patent 9,366,808 (Issuedon June 14, 2016).61.A. P. Raman, S. Fan and E. Rephaeli, “Structures for radiative cooling”, U. S.Patent 9,709,349 (Issued on July 18, 2017).62.H. Iizuka and S. Fan, “Thermal rectification device”, U. S. Patent 9,791,183 (Issuedon October 17, 2017).63.S. Fan, A. P. Raman, L. Zhu, and E. Rephaeli, “Illumination and radiative skycooling”, U. S. Patent 9,923,111, (Issued on March 20, 2018).64.A. P. Raman, S. Fan, E. Rephaeli, L. Zhu, M. Anoma, and E. Goldstein, “Radiativecooling with solar spectrum reflection”, U. S. Patent 10,088,251 (Issued on October2, 2018).65.Z. Chen, L. Zhu, A. Raman, E. Goldstein and S. Fan, “Ultrahigh-performanceradiative cooler”, U. S. Patent 10,508,838 (Issued on December 17, 2019).66.Z. Yu, N. Sergeant, T. Skauli, G. Zhang, H. Wang, and S. Fan, “Thermal extractionusing radiation”, U. S. Patent 10,544,999 (Issued on January 28, 2020).9
67.W. Joo, J. Kang, S. Kim, M. Brongersma, and S. Fan, “Multi-stack graphenestructure and device including the same”. U. S. Patent 10,816,818 (Issued onOctober 27, 2020).68.C. Guo, M. Xiao, M. Minkov, Y. Shi and S. Fan, “Isotropic filters in spatialfrequency domain by a photonic crystal slab”, U. S. Patent 10,928,551 (Issued onFebruary 23, 2021).69.S. Fan, S. Assawaworrarit, and X. Yu, “Methods and apparatus for wireless transferof power”, U. S. Patent 10,931,146 (Issued on February 23, 2021).70.A. Raman, S. Fan, and E. Rephaeli, “Structures for radiative cooling”, U. S. Patent10,941,990 (Issued on March 9, 2021).71.W. Joo, J. Kang, S. Kim, M. Brongersma and S. Fan, “Multi-stack graphenestructure and device including the same”, U. S. Patent 11,067,836 (Issued on July20,2021).Plenary or Keynote Talks and Distinguished Lectures1.Plenary Talk, “Manipulating light with photonic crystals”, The 7th InternationalWorkshop on Femtosecond Technology, Tsukuba, Japan, June 2000.2.Plenary Talk, "Three-dimensional guiding of light in photonic crystal slabs",European Optical Society Topical Meeting on Two Dimensional Photonic Crystals,Monte Verita, Ascona, Switzerland, August 2002.3.Keynote Talk, “Theory and simulations of meta-materials”, NATO AdvancedResearch Workshop: META’10, 2nd International Conference on Metamaterials,Photonic Crystals, and Plasmonics, Cairo, Egypt, February 22, 2010.4.The Global Energy and Climate Project Distinguished Lecturer, 2011.5.Frontiers in Engineering Innovation Judd Distinguished Lectures, “Explorations ofnanophotonics”, Department of Electrical Engineering, University of Utah, SaltLake City, Utah, February 14, 2011.6.Plenary Lecture, “Theory and Practice for Nanophotonic Light Trapping”, OSATopical Meeting on Renewal Energy and the Environment, November 3, 2011,Austin, Texas.7.Plenary Talk, “Nanophotonics: solar and thermal applications”, SPIE SmartNano Micro Materials and Devices, December 7, 2011, Swinburne University ofTechnology/Hawthorn Campus, Melbourne, Australia.8.Keynote Talk, “Nanophotonics for the control of thermal electromagnetic fields”,in International Workshop on Nano-Micro Thermal Radiation, May 22, 2012, HotelMatsushima Taikanso, Sendai, Japan.9.Distinguished Speaker, “Nanophotonics for energy and information applications”,Department of Electrical and Computational Engineering, Purdue University,December 13, 2012, West Lafayette, Indiana.10.Keynote Talk, “Broadband management of light using nanophotonics for solar and10
thermal applications”, International Quantum Electronics Conference (IQEC), May15, 2013, Munich, Germany.11.MPL Distinguished Lecturer Series, “Nanophotonics: gauge field for photons andcontrol of heat”, the Max Planck Institute for the Science of Light, June 6, 2013,Erlangen, Germany.12.Plenary Talk, “Non-reciprocity in optics without magneto-optics”, IEEE PhotonicsSociety Summer Topical Meeting on Non-Reciprocal Photonic Devices, HiltonWaikoloa Village, Hawaii, July 8, 2013.13.Plenary Talk, “Nanophotonics fundamentals and applications: gauge field forphotons and control of heat”, MESA Meeting 2013, University of Twente,Enschede, Netherlands, September 16, 2013.14.Plenary Talk, “Photonic structures: advanced thermal control, and effective gaugefield for light”, Metamaterials 2013: the 7th International Conference on AdvancedElectromagnetic Materials in Microwave and Optics, Bordeaux, France, September18, 2013.15.Keynote Talk, “New physics of nanophotonics for information and energyapplications”, the 19th Optoelectronics and Communications Conference(OECC/ACOFT 2014), Melbourne, Australia, July 7, 2014.16.Distinguished Lecture, “Nanophotonics for energy and information applications:photonic gauge field, and daytime radiative cooling”, Department of Electrical andComputer Engineering, University of Toronto, Toronto, Canada, September 18,2014.17.Keynote Lecture, “Nanophotonic control of thermal radiation: maximal violationof detailed balance, and experimental demonstration of daytime radiative cooling”,Eurotherm 103: Nanoscale and Microscale Heat Transfer IV, Lyon, France,October 16, 2014.18.Keynote Lecture, “Nanophotonic control of thermal radiation to enable new energyapplications”, OSA Incubator Meeting on the Fundamental Limit of Optical EnergyConversion, Washington DC, November 14, 2014.19.Plenary Lecture, “Nanophotonic structures for information and energyapplications: dynamic structures, and radiative cooling”, The 5th InternalConference on Advances in Optoelectronics and Micro/Nanooptics (AOM2015),Hangzhou, China, October 29, 2015.20.Keynote Lecture, “Controlling current, voltage and heat in a solar cell withphotonic nanostructures”, The Optical Nanostructures and Advanced Materials forPV, OSA Light, Energy and Environment Congress, Suzhou, China, November 3,2015.21.Plenary Lecture, “Nanophotonics: controlling the flow of light and heat”, in Dayson Diffraction, St Petersburg, Russia, June 28, 2016.22.Keynote Lecture, “Dynamic modulation approach to topological photonics”, inActive Photonic Materials VIII, the SPIE Annual Meeting, San Diego, California,11
August 31, 2016.23.Plenary Lecture, “Shaping the flow of light and heat with nanophotonic structures”,Photon 2016 Conference, University of Leeds, Leeds, United Kingdom, September8, 2016.24.Plenary Lecture, “Non-reciprocal photonic gauge potential and non-equilibriumthermal metaphotonics for the control of light and heat”, SPIE Photonics West,Opto Plenary Session, January 30, 2017.25.“Topological and complex birefringent metamaterial”, Keynote Talk, ActivePhotonic Platform Conference IX, SPIE Annual Meeting, San Diego, California,August 9, 2017.26.Plenary Talk, "Nanophotonic concepts for energy applications", InternationalConference on Nanoscience and Nanotechnology (ICONN-2018), University ofWollongong, Australia, February 1, 2018.27.Keynote Talk, “Non-Hermitian and topological electromagnetics: syntheticdimension, and robust wireless power transfer”, IEEE Summer Topical Meeting onNon-Hermitian, Topological and Active Photonics, Hilton Waikaloa Village,Waikaloa, Hawaii, July 9, 2018.28.Keynote Talk, “Nanophotonic Control of Thermal Radiation for EnergyApplications”, XXV International Summer School ‘Nicolás Cabrera’ onManipulating Light and Matter at the Nanoscale, Miraflores de la Sierra, Madrid,Spain, September 13, 2018.29.USTC Alumni Keynote Talk, “Nanophotonics and Energy Applications”, 4thInternational Conference on Energy and Biological Materials, University ofScience and Technology of China, Hefei, China, September 17, 2018.30.Distinguished Lecture, “Concepts of Nanophotonics and Energy Applications”,Institute of Molecular Engineering, University of Chicago, November 7, 2018.31.Plenary Talk, “Nanophotonic concepts for thermal and energy applications”,Nature Conference on Nanophotonics and Integrated Photonics, Nanjing, China,November 11, 2018.32.Plenary Talk, “Nanophotonics: fundamental advances and energy applications”,Smart Nanomaterials 2018: Advances, Innovations and Applications, ÉcoleNationale Supérieure de Chimie de Paris, Paris, December 11, 2018.33.Keynote Talk, “Aspects of analog optical computing using nanophotonicstructures”, Active Photonic Platforms XI, SPIE Annual Meeting, San Diego,California, August 14, 2019.34.Distinguishes Seminar Series, “Control of electromagnetic fields for energyapplications”, University of Michigan Department of Electrical Engineering andComputer Science, Ann Arbor, Michigan, February 28, 2020.35.Plenary Talk, “Thermodynamics of light and the implication for harvesting solarenergy and the coldness of the universe", the 47th IEEE Photovoltaic Specialists12
Conference (PVSC), June 19, 2020 (presented online).36.Keynote Talk, "Exploring non-trivial topology in synthetic dimensions", ActivePhotonic Platforms XI, SPIE Annual Meeting, August 25, 2020 (Presented Online).37.Plenary Talk, "Topology in Synthetic and Momentum Spaces", In MetaNano 2020,September 16, 2020 (presented online).38.Keynote Talk, “Using Photonic Structures to Compute”, in the 2nd InternationalConference of Future Technology and Disruptive Innovation, October 26, 2020,Hangzhou, China (presented online).39.Plenary Talk, “Topology in the Frequency Synthetic Dimension”, in the Waves inTime-Varying Media Workshop Series, organized by Imperial College London.March 31, 2021 (presented online).40.Plenary Talk, “Synthetic Dimension: Topological Physics and Optical Computing”,in the OSA Advanced Photonics Congress, July 26, 2021 (presented online).41.Keynote Talk, “Creating Non-Trivial Space-Time Correlation with WavevectorSpace Metasurface”, in the Symposium OP21N: Active Photonic Platforms XIII,SPIE Nanoscience Engineering, August 3, 2021 (presented online).42.Keynote Talk, “Controlling electromagnetic and optical fields for energyapplications”, Chinese Physical Society (CPS) – American Physical Society (APS)Joint Session on Energy and Sustainability, Beijing, China, October 23, 2021(presented online).43.Plenary Talk, “Explorations of topological photonics in synthetic dimensions”,Asia Communications and Photonics Conference (ACP), Shanghai, China, October24, 2021. (presented online).Invited Talks44.“Photonic Crystal Light Emitting Diodes”, SPIE Photonics West Conference onLight Emitting Diodes: Research, Manufacturing and Applications, San Jose,California, February 1997.45.“Photonic Crystals Probed by Near-Field Microscopy”, Workshop onElectromagnetic Crystal Structures, Design, Synthesis, and Applications, LagunaBeach, California, January 1999.46.“Photonic Crystals: Challenges and Expectations”, International Topical Workshopon Contemporary Photonic Technologies, Sendai, Japan, January 1999.47.“Photonic Crystals and Device Applications”, Progress in ElectromagneticsResearch Symposium, Taipei, Taiwan, March 1999.48.“Photonic crystals for precision control of photon propagation and storage”, MITSixth Annual Research Directors Conference, Cambr
4 Photonic and Phononic Crystal Materials and Devices VIII, SPIE Photonics West, 2009. The 53rd International Conference on Electron, Ion and Photon Beam Technology and Nanofabrication (EIPBN), 2009. Physics and Simulation of Optoelectronic Devices XVIII, SPIE Photonics Photonics West, 2010. Advances in Slow and Fast Light III, SPIE Photonics West, 2010.
calculation. FAN SPEED 0000 RPM Displays fan real time speed based on the fan frequency reading. FAN OUTPUT FREQUENCY 000.0 Hz Displays the output frequency of the fan inverter. FAN OUTPUT CURRENT 000.0 A Displays the output current of the fan inverter. FAN OUTPUT VOLTAGE 000.0 V Displays output voltage of the fan inverter. FAN OUTPUT POWER
Curriculum Vitae Guide The terms curriculum and vitae are derived from Latin and mean "courses of my life". Résumé, on the other hand, is French for “summary.” In industry, both in and outside of the US, people refer to curriculum vitae (CV)s and résumés interchangeably. Curriculum Vitae vs. Résumés
CV curriculum vitae CV v. resume – Length – Scholarly/scientific. Curriculum Vitae CV curriculum vitae CV v. resume – Length – Scholarly/scientific – Detailed. Curriculum Vitae (CV) Name, title, curren
b. "High": Fan operates continuously at high speed. Heat strip cycles On and Off. c. "Auto": Fan operates in low speed and will cycle On and Off with thermostat. F. "Fan" - Fan Mode 1. There are 3 fan speeds in Fan mode. a. "Low": Fan operates continuously at low speed. b. "High": Fan operates continuously at high speed.
Accelerated solution of the frequency-domain Maxwell’s equations by engineering the eigenvalue distribution of the operator Wonseok Shin 1,2 and Shanhui Fan1, 1Department of Electrical Engineering, Stanford University, Stanford, CA 94305, USA 2wsshin@stanford.edu shanhui@stanford.edu Abstract: W
Fan speed control panel provides Smart Fan and Manual Fan. You can switch the control mode by clicking the Smart Fan and Manual Fan buttons on the top of the Fan control panel. How to enter the fan speed control panel 1. On Home tab Performance option dialog window, select Profile 1 or Profile 2. 2. You may need to click to switch to page 2. 3.
speed of the fan. Pressing and holding the" " button for more than 1 second to begin adjusting the fan speeds from Low to High cycle and the increments will be denoted on the indicator LED. If the fan is OFF, the fan speed indicator LEDs will also be off. Fan control with automatic speed memory. The " "button: Controls fan direction.
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