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Vladimir Shalaev

January 01, 1970

Vladimir (Vlad) M. Shalaev (born February 18, 1957) is a Distinguished Professor of Electrical and Computer Engineering[13] and Scientific Director for Nanophotonics at Birck Nanotechnology Center,[14] Purdue University.

Vladimir M. Shalaev
Born (1957-02-18) February 18, 1957 (age 67)
Krasnoyarsk, Russia
CitizenshipUnited States
Alma materKrasnoyarsk State University, Russia
AwardsMax Born Award, Optica (2010) [1]

Willis E. Lamb Award for Laser Science and Quantum Optics [2]

IEEE Photonics Society William Streifer Scientific Achievement Award [3]

Rolf Landauer Medal, ETOPIM International Association [4]

UNESCO Medal for the development of nanosciences and nanotechnologies [5]

Goodman Book Writing Award, OSA and SPIE [6]

Frank Isakson Prize for Optical Effects in Solids [7]

Fellow of Professional Societies: OSA,[8] IEEE,[9] SPIE,[10] APS,[11] MRS.[12]
Scientific career
Fields
InstitutionsPurdue University
Websiteengineering.purdue.edu/~shalaev/

Education and career edit

V. Shalaev earned a Master of Science Degree in physics (summa com laude) in 1979 from Krasnoyarsk State University (Russia) and a PhD Degree in physics and mathematics in 1983 from the same university. Over the course of his career, Shalaev received a number of awards for his research in the fields of nanophotonics and metamaterials, and he is a Fellow of several of Professional Societies (see the Awards, honors, memberships section below). Prof. Shalaev has co-/written three- and co-/edited four books, and authored over 800 research publications, in total.[15] As of May 2024, his h-index is 125 with the total number of citations nearing 70,000, according to Google Scholar.[16] In 2017-2023 Prof. Shalaev has been on the list of Highly Cited Researchers from the Web of Science Group;[17] he is ranked #9 in the optics category of the Stanford list of top 2% World's highest-cited scientists[18] (career-long; out of 64,044 entries); ranked #34 in the US and #58 worldwide in the field of Electronics and Electrical Engineering by Research.com.[19]

Research edit

Vladimir M. Shalaev is recognized for his pioneering studies on linear and nonlinear optics of random nanophotonic composites that had helped to mold the research area of composite optical media.[2] He also contributed to the emergence of a new field of engineered, artificial materials - optical metamaterials.[1][2] Currently, he studies new phenomena resulting from merging metamaterials and plasmonics with quantum nanophotonics.[20]

Optical metamaterials edit

Optical metamaterials (MMs) are rationally designed composite nanostructured materials that exhibit unique electromagnetic properties drastically different from the properties of their constituent material components. Metamaterials offer remarkable tailorability of their electromagnetic response via shape, size, composition and morphology of their nanoscale building blocks sometimes called 'meta-atoms'.[21] Shalaev proposed and demonstrated the first optical MM that exhibits negative index of refraction and the nanostructures that show artificial magnetism across the entire visible spectrum.[22][23][24][25] (Here and thereafter, only selected, representative papers by Shalaev are cited; for complete list of Shalaev's publications visit his website.[26]) He made important contributions to active, nonlinear and tunable metamaterials, which enable new ways of controlling light and accessing new regimes of enhanced light-matter interactions.[27][28][29][30] Shalaev also experimentally realized negative-refractive-index MMs where optical gain medium is used to compensate for light absorption (optical loss).[29] He made significant contributions to the so-called Transformation Optics,[31] specifically on optical concentrators and "invisibility cloaks".[32][33][34][35] In collaboration with Noginov, Shalaev demonstrated the smallest, 40-nm, nanolaser operating in the visible spectral range.[36][37] Shalaev also made seminal contributions to two dimensional, flat metamaterials – metasurfaces[38] – that introduce abrupt changes to the phase of light at a single interface via coupling to nanoscale optical antennas.[39][40][41][42][43] He realized extremely compact flat lens,[41] ultra-thin hologram[42] and record-small circular dichroism spectrometer[43] compatible with planar optical circuitry. MM designs developed by Shalaev are now broadly employed for research in sub-wavelength optical imaging, nanoscale lasers, and novel sensors.[38][44]

Shalaev’s work had a strong impact on the whole field of metamaterials.[1][2][3] Three of Shalaev’s papers - Refs. [22], [23], and [32] - remain among the top 50 most-cited out of over 750,000 papers included in the ISI Web of Science OPTICS category since 2005 (as of January 2021).[45]

Random composites edit

Shalaev made pioneering contributions to the area of random optical media, including fractal and percolation composites.[2][46][47][48][49][50][51][52][53][54][55][56] He predicted the highly localized optical modes -'hot spots' - for fractals and percolating films which were later experimentally demonstrated by Shalaev in collaboration with the Moskovits and Boccara groups.[52][53] Furthermore, he showed that the hot spots in fractal and percolation random composites are related to localization of surface plasmons.[46][56] These localized surface plasmon modes in random systems are sometimes referred to as  Shalaev's "hot spots": see e.g.[57] This research on random composites stemmed from the early studies on fractals performed by Shalaev in collaboration with M. I. Stockman;[58][59][60][61][62][63] a theory of random metal-dielectric films was worked out in collaboration with A. K. Sarychev.[47][49][50][54] Shalaev also developed fundamental theories of surface-enhanced Raman scattering (SERS) and strongly-enhanced optical nonlinearities in fractals and percolation systems and led experimental studies aimed to verify the developed theories.[46][56][60][64][65] Shalaev also predicted that nonlinear phenomena in random systems can be enhanced not only because of the high local fields in hot spots but also due to the rapid, nanoscale spatial variation of these fields in the vicinity of hot spots, which serves as a source of additional momentum and thus enables indirect electronic transitions.[65]

Shalaev’s contributions to the optics and plasmonics of random media[46][56] helped to transform those concepts into the area of optical metamaterials.[22][25][27][36] Owing to the theory and experimental approaches developed in the area of random composites, optical metamaterials have quickly become a mature research field surprisingly rich in new physics.[24][4] Shalaev’s impact on the development of both fields is in identifying the strong synergy and close connection between these two frontier fields of optics that unlock an entirely new set of physical properties.[4]

New Materials for Nanophotonics and Plasmonics edit

Random composites and metamaterials provide a unique opportunity to tailor their optical properties via shape, size and composition of their nanoscale building blocks, which often require metals to confine light down to the nanometer scale via the excitation of surface plasmons.[46][30] To enable practical applications of plasmonics, Shalaev in collaboration with A. Boltasseva[66] developed novel plasmonic materials, namely transition metal nitrides and transparent conducting oxides (TCOs), paving the way to durable, low-loss, and CMOS-compatible plasmonic and nanophotonic devices.[67][68][69][70][71][72][73] The proposed plasmonic ceramics operating at high temperatures, can offer solutions to highly efficient energy conversion, photocatalysis and data storage technologies[69].[73] In collaboration with the Faccio group,[74] Shalaev demonstrated ultrafast, strongly-enhanced nonlinear responses in TCOs that possess an extremely low (close to zero) linear refractive index – the so-called epsilon-near-zero regime.[75][76][77][78][79] Independently, the Boyd group obtained equally remarkable results in a TCO material,[80] demonstrating that low-index TCOs hold a promise for novel nonlinear optics.

Early research edit

Shalaev’s PhD work (supervised by Prof. A.K. Popov) and early research involved theoretical analysis of resonant interaction of laser radiation with gaseous media, in particular i) Doppler-free multi-photon processes in strong optical fields and their applications in nonlinear optics[81] spectroscopy[82] and laser physics[83] as well as ii) the (newly-discovered then) phenomenon of light-induced drift of gases.[84][85]

Awards, honors, memberships edit

  • Recognized as Highly Cited Researcher by the Web of Science Group in 2017-2022;[17]
  • Ranked #9 in the optics category of the Stanford list of top 2% World's highest-cited scientists[18] (career-long; out of 64,044 entries)
  • Ranked #28 in electronics and electrical engineering among top USA researchers, according to Research.com.
  • The 2020 Frank Isakson Prize for Optical Effects in Solids[7]
  • The Optical Society of America Max Born Award, 2010[1]
  • The Willis E. Lamb Award for Laser Science and Quantum Optics, 2010[2]
  • IEEE Photonics Society William Streifer Scientific Achievement Award, 2015[3]
  • Rolf Landauer Medal of the ETOPIM (Electrical, Transport and Optical Properties of Inhomogeneous Media) International Association, 2015[4]
  • The 2012 Nanotechnology Award from UNESCO[5]
  • The 2014 Goodman Book Award from OSA and SPIE[6]
  • Honorary Doctorate from University of Southern Denmark, 2015
  • The 2006 Top 50 Nano Technology Award Winner for “Nanorod Material”
  • The 2009 McCoy Award, Purdue University's highest honor for scientific achievement
  • Fellow of the Materials Research Society (MRS),[12] since 2015
  • Fellow of the Institute of Electrical and Electronics Engineers (IEEE),[9] since 2010
  • Fellow of the American Physical Society (APS),[11] since 2002
  • Fellow of the Optical Society of America (OSA),[8] since 2003
  • Fellow of the International Society for Optical Engineering (SPIE),[10] since 2005
  • General co-Chair for 2011 and Program co-Chair 2009 of CLEO/QELS conferences
  • Chair of the OSA Technical Group “Photonic Metamaterials”, 2004 - 2010
  • Reviewing Editor for Science Science Magazine
  • Co-Editor of Applied Physics B - Lasers and Optics, 2006 - 2013
  • Topical Editor for Journal of Optical Society of America B, 2005–2011
  • Editorial Board Member for Nanophotonics journal, since 2012
  • Editorial Advisory Board Member for Laser and Photonics Reviews, since 2008

Publications edit

Prof. Shalaev co-/authored three-[24][48][50] and co-/edited four[86][87][88][89] books in the area of his scientific expertise. According to Shalaev's website,[90] over the course of his career he contributed 30 invited chapters to various scientific anthologies and published a number of invited review articles, over 800 publications in total. He made over 500 invited presentations at International Conferences and leading research centers, including a number of plenary and keynote talks.[91][92]

References edit

  1. ^ a b c d 2010 Optical Society of America Max Born Award
  2. ^ a b c d e f 2010 Willis E. Lamb Award for Laser Science and Quantum Optics
  3. ^ a b c 2015 IEEE Photonics Society William Streifer Scientific Achievement Award
  4. ^ a b c d 2015 Rolf Landauer International ETOPIM Association Medal
  5. ^ a b 2012 UNESCO Medal for the Development of Nanosciences and Nanotechnologies
  6. ^ a b 2014 Joseph W. Goodman Book Writing Award
  7. ^ a b 2020 Frank Isakson Prize for Optical Effects in Solids
  8. ^ a b 2003 OSA Fellows
  9. ^ a b IEEE Fellows Directory
  10. ^ a b Complete List of SPIE Fellows
  11. ^ a b APS Fellow Archive
  12. ^ a b List of MRS Fellows
  13. ^ People, School of Electrical and Computer Engineering, Purdue University
  14. ^ Birck Nanotechnology Center Faculty
  15. ^ V. Shalaev's publication list
  16. ^ Shalaev h-index and citations, Google Scholar
  17. ^ a b V. Shalaev - webofscience.com
  18. ^ a b "Updated science-wide author databases of standardized citation indicators, September 2022"
  19. ^ "Research.com: Best Scientists - Electronics and Electrical Engineering"
  20. ^ S. I. Bogdanov, A. Boltasseva, V. M. Shalaev, Overcoming quantum decoherence with plasmonics, Science, v. 364, no. 6440, pp. 532-533 (2019)
  21. ^ N. Meinzer, W.L. Barnes & I.R. Hooper, Plasmonic meta-atoms and metasurfaces, N. Meinzer, William L. Barnes & I.R. Hooper, Nature Photonics, v. 8, pp. 889–898 (2014)
  22. ^ a b c V.M. Shalaev, Optical Negative-Index Metamaterials, Nature photonics, v. 1, pp. 41–48 (2007)
  23. ^ a b V.M. Shalaev, W. Cai, U.K. Chettiar, H.-K. Yuan, A.K. Sarychev, V.P. Drachev, and A.V. Kildishev, Negative Index of Refraction in Optical Metamaterials, Optics Letters, v. 30, pp. 3356–3358 (2005)
  24. ^ a b c W. Cai, V.M. Shalaev, Optical Metamaterials: Fundamentals and Applications, Springer-Verlag, New York (2010)
  25. ^ a b W. Cai, U.K. Chettiar, H.-K. Yuan, V.C. de Silva, A.V. Kildishev, V.P. Drachev, and V.M. Shalaev, Metamagnetics with rainbow colors, Optics Express, v. 15, pp. 3333–3341 (2007)
  26. ^ Prof. V. Shalaev, Purdue University, Electrical & Computer Engineering
  27. ^ a b A.K. Popov and V.M. Shalaev, Negative-index metamaterials: second-harmonic generation, Manley-Rowe relations and parametric amplification, Applied Physics B, v. 84, pp. 131–37 (2006)
  28. ^ S. Xiao, U.K. Chettiar, A.V. Kildishev, V.P. Drachev, I.C. Khoo, and V.M. Shalaev, Tunable magnetic response of metamaterials, Applied Physics Letters, v. 95, p. 033114 (2009)
  29. ^ a b S. Xiao, V.P. Drachev, A.V. Kildishev, X. Ni, U.K. Chettiar, H.-K. Yuan, and V.M. Shalaev, Loss-free and active optical negative-index metamaterials, Nature, v. 466, pp. 735–738 (2010)
  30. ^ a b O. Hess, J. B. Pendry, S. A. Maier, R. F. Oulton, J. M. Hamm and K. L. Tsakmakidis, Active nanoplasmonic metamaterials, Nature Materials, v. 11, pp. 573-584 (2012)
  31. ^ H. Chen, C.T. Chan and P. Sheng, Transformation optics and metamaterials, Nature Materials, v. 9, pp. 387–396 (2010)
  32. ^ a b W. Cai, U.K. Chettiar, A.V. Kildishev and V.M. Shalaev, Optical cloaking with metamaterials, Nature Photonics, v. 1, pp. 224-227 (2007)
  33. ^ I.I. Smolyaninov, V.N. Smolyaninova, A.V. Kildishev, and V.M. Shalaev, Anisotropic Metamaterials Emulated by Tapered Waveguides: Application to Optical Cloaking, Physical Review Letters, v. 102, p. 213901 (2009)
  34. ^ V.M. Shalaev, Transforming Light, Science, v. 322, pp. 384–386 (2008)
  35. ^ A.V. Kildishev and V.M. Shalaev, Engineering space for light via transformation optics, Optics Letters, v. 33, pp. 43–45 (2008)
  36. ^ a b M. A. Noginov, G. Zhu, A. M. Belgrave, R. Bakker, V. M. Shalaev, E. E. Narimanov, S. Stout, E. Herz, T. Suteewong and U. Wiesner, Demonstration of a spaser-based nanolaser, Nature, v. 460, pp.1110–1112 (2009)
  37. ^ M. Premaratne and M.I. Stockman, Theory and Technology of SPASERs, Advances In Optics And Photonics, v. 9, pp. 79–128 (2017)
  38. ^ a b N. Yu, and F. Capasso, Optical Metasurfaces and Prospect of Their Applications Including Fiber Optics, Journal Of Lightwave Technology, v. 33, pp.2344–2358 (2015)
  39. ^ X. Ni, N. K. Emani, A.V. Kildishev, A. Boltasseva, and V.M. Shalaev, Broadband light bending with plasmonic nanoantennas, Science, v. 335, pp. 427 (2012)
  40. ^ A. V. Kildishev, A. Boltasseva, and V. M. Shalaev, Planar photonics with metasurfaces, Science, v. 339, p. 1232009 (2013)
  41. ^ a b X. Ni, S. Ishii, A.V. Kildishev, and V.M. Shalaev, Ultra-thin, planar, Babinet-inverted plasmonic metalenses, Light: Science & Applications, v. 2, p. e72 (2013)
  42. ^ a b X. Ni, A.V. Kildishev, and V.M. Shalaev, Metasurface holograms for visible light, Nature Communications, v. 4, pp. 1–6 (2013)
  43. ^ a b A. Shaltout, J. Liu, A. Kildishev, and V. Shalaev, Photonic spin Hall effect in gap-plasmon metasurfaces for on-chip chiroptical spectroscopy, Optica, v. 2, pp. 860-863 (2015)
  44. ^ C. Deeb, J.-L. Pelouard, Plasmon lasers: coherent nanoscopic light sources, Physical Chemistry Chemical Physics, v. 19, pp. 29731–29741 (2017)
  45. ^ Web of Science Core Collection Search Results
  46. ^ a b c d e V. M. Shalaev, Electromagnetic Properties of Small-Particle Composites, Physics Reports, v. 272, pp. 61–137 (1996)
  47. ^ a b V.M. Shalaev and A.K. Sarychev, Nonlinear optics of random metal-dielectric films, Physical Review B, v. 57, pp. 13265-13288 (1998)
  48. ^ a b V. M. Shalaev, Nonlinear Optics of Random Media: Fractal Composites and Metal-Dielectric Films, Springer (2000)
  49. ^ a b A.K. Sarychev, V.M. Shalaev, Electromagnetic field fluctuations and optical nonlinearities in metal-dielectric composites, Physics Reports, v. 335, pp. 275–371 (2000)
  50. ^ a b c A.K. Sarychev, V.M. Shalaev, Electrodynamics of Metamaterials, World Scientific (2007)
  51. ^ M.I. Stockman, V.M. Shalaev, M. Moskovits, R. Botet, T.F. George, Enhanced Raman scattering by fractal clusters: Scale-invariant theory, Physical Review B, v. 46, pp. 2821–2830 (1992)
  52. ^ a b D.P. Tsai, J. Kovacs, Zh. Wang, M. Moskovits, V.M. Shalaev, J.S. Suh, and R. Botet, Photon Scanning Tunneling Microscopy Images of Optical Excitations of Fractal Metal Colloid Clusters, Physical Review Letters, v. 72, pp. 4149–4152, (1994)
  53. ^ a b S. Gresillon, L. Aigouy, A.C. Boccara, J.C. Rivoal, X. Quelin, C. Desmarest, P. Gadenne, V.A. Shubin, A.K. Sarychev, and V.M. Shalaev Experimental Observation of Localized Optical Excitations in Random Metal-Dielectric Films, Physical Review Letters, v. 82, pp. 4520-4523 (1999)
  54. ^ a b A.K. Sarychev, V.A. Shubin, and V.M. Shalaev, Anderson localization of surface plasmons and nonlinear optics of metal-dielectric composites, Physical Review B, v. 60, pp. 16389–16408 (1999)
  55. ^ V.P. Safonov, V.M. Shalaev, V.A. Markel, Yu.E. Danilova, N.N. Lepeshkin, W. Kim, S.G. Rautian, and R.L. Armstrong, Spectral Dependence of Selective Photomodification in Fractal Aggregates of Colloidal Particles, Physical Review Letters, v. 80, pp. 1102–1105 (1998)
  56. ^ a b c d W. Kim, V.P. Safonov, V.M. Shalaev, and R.L. Armstrong, Fractals in Microcavities: Giant Coupled Multiplicative Enhancement of Optical Responses, Physical Review Letters, v. 82, pp. 4811–4814 (1999)
  57. ^ A. Otto, On the significance of Shalaev's 'hot spots' in ensemble and single‐molecule SERS by adsorbates on metallic films at the percolation threshold, J. Raman Spectroscopy, v. 37, pp. 937–947 (2006)
  58. ^ V.M. Shalaev, M.I. Stockman, Fractals: optical susceptibility and giant Raman scattering, Zeitschrift für Physik D - Atoms, Molecules and Clusters, v. 10, pp. 71–79 (1988)
  59. ^ A.V. Butenko, V.M. Shalaev, M.I. Stockman, Fractals: giant impurity nonlinearities in optics of fractal clusters, Zeitschrift für Physik D - Atoms, Molecules and Clusters, v. 10, pp. 81-92 (1988)
  60. ^ a b S.G. Rautian, V.P. Safonov, P.A. Chubakov, V.M. Shalaev, M.I. Shtockman, Surface-enhanced parametric scattering of light by silver clusters, JETP Lett. v. 47, pp. 243–246 (1988) (translated from Zh.Eksp.Teor.Fiz. v. 47, pp. 20–203 (1988))
  61. ^ A.V. Butenko, P.A. Chubakov, Yu.E. Danilova, S.V. Karpov, A.K. Popov, S.G. Rautian, V.P. Safonov, V.V. Slabko, V.M. Shalaev, M.I. Stockman, Nonlinear optics of metal fractal clusters, Zeitschrift für Physik D Atoms, Molecules and Clusters, v. 990, pp. 283-289 (1990)
  62. ^ V.M. Shalaev, R. Botet, R. Jullien, Resonant light scattering by fractal clusters, Physical Review B, v. 44, pp. 12216–12225 (1991)
  63. ^ V.M. Shalaev, M.I. Stockman, and R. Botet, Resonant excitations and nonlinear optics of fractals, Physica A, v. 185, pp. 181–186 (1992)
  64. ^ M. Breit, V. A. Podolskiy, S. Gresillon, G. von Plessen, J. Feldmann, J. C. Rivoal, P. Gadenne, A. K. Sarychev, and Vladimir M. Shalaev, Experimental observation of percolation-enhanced non-linear light scattering from semicontinuous metal films, Physical Review B, v. 64, p. 125106 (2001)
  65. ^ a b V.M. Shalaev, C. Douketis, T. Haslett, T. Stuckless, and M. Moskovits, Two-photon electron emission from smooth and rough metal films in the threshold region, Physical Review B, v. 53, p. 11193 (1996)
  66. ^ Prof. A. Boltasseva's research group site
  67. ^ P.R. West, S. Ishii, G.V. Naik, N.K. Emani, V.M. Shalaev, and A. Boltasseva, Searching for better plasmonic materials, Laser & Photonics Reviews, v. 4, pp. 795–808 (2010)
  68. ^ G.V. Naik, V.M. Shalaev, and A. Boltasseva, Alternative Plasmonic Materials: Beyond Gold and Silver, Advanced Materials, v. 25, pp. 3264–3294 (2013)
  69. ^ a b U. Guler, A. Boltasseva, and V. M. Shalaev, Refractory plasmonics, Science, v. 344, pp. 263–264 (2014)
  70. ^ U. Guler, V.M. Shalaev, A. Boltasseva, Nanoparticle Plasmonics: Going Practical with Transition Metal Nitrides, Materials Today, v. 18, pp. 227–237 (2014)
  71. ^ U. Guler, A. Kildishev, A. Boltasseva, and V.M. Shalaev, Plasmonics on the slope of enlightenment: the role of transition metal nitrides, Faraday Discussions, v. 178, pp. 71–86 (2015)
  72. ^ A. Boltasseva and V.M. Shalaev, All that glitters need not be gold, Science, v. 347, pp. 1308-1310 (2015)
  73. ^ a b A. Naldoni, U. Guler, Zh. Wang, M. Marelli, F. Malara, X. Meng, A.V. Kildishev, A. Boltasseva, V.M. Shalaev, Broadband Hot Electron Collection for Solar Water Splitting with Plasmonic Titanium Nitride, Advanced Optical Materials, v. 5, p. 1601031 (2017)
  74. ^ Prof. D. Faccio group, Heriot-Watt University, UK
  75. ^ L. Caspani, R.P.M. Kaipurath, M. Clerici, M. Ferrera, T. Roger, A. Di Falco, J. Kim, N. Kinsey, V. M. Shalaev, A. Boltasseva, D. Faccio, Enhanced Nonlinear Refractive Index in ε-Near-Zero Materials, Physical Review Letters, v. 116, p. 233901 (2016)
  76. ^ M. Clerici, N. Kinsey, C. DeVault, J. Kim, E. G. Carnemolla, L. Caspani, A. Shaltout, D. Faccio, V. Shalaev, A. Boltasseva, M. Ferrera, Controlling hybrid nonlinearities in transparent conducting oxides via two-colour excitation, Nature Communications v. 8, p. 15829 (2017)
  77. ^ S. Vezzoli, V. Bruno, C. DeVault, T. Roger, V.M. Shalaev, A. Boltasseva, M. Ferrera, M. Clerici, A. Dubietis, and D. Faccio1, Optical time reversal from time-dependent epsilon-near-zero media, Physical Review Letters, v. 120, p. 043902 (2018)
  78. ^ V. Bruno, C. DeVault, S. Vezzoli, D. Shah, S. Maier, A. Jacassi, S. Minguzzi, T. Huq, Z. Kudyshev, S. Saha, A. Boltasseva, M. Ferrera, M. Clerici, D. Faccio, R. Sapienza, V. Shalaev, Negative refraction in time-varying, strongly coupled plasmonic antenna-ENZ systems, Physical Review Letters, 124 (4), 043902 (January 30, 2020)
  79. ^ N. Kinsey, C. DeVault, A. Boltasseva, V. M. Shalaev, Near-zero-index materials for photonics, Nature Reviews Materials, v. 4, pp. 742–760 (2019)
  80. ^ M.Z. Alam, I. De Leon, R.W. Boyd, Large optical nonlinearity of indium tin oxide in its epsilon-near-zero region, Science, v. 352, pp. 795–797 (2016)
  81. ^ A.K. Popov, V.M. Shalaev, Doppler-free transitions induced by strong double-frequency optical excitations, Optics Communications, v. 35, pp. 189–193 (1980)
  82. ^ A.K. Popov, V.M. Shalaev, Doppler-free spectroscopy and wave-front conjugation by four-wave mixing of nonmonochromatic waves, Applied Physics, v.21, pp. 93–94 (1980)
  83. ^ A.K. Popov, V.M. Shalaev, Unidirectional Doppler-Free Gain And Generation In Optically Pumped Lasers, Applied Physics B, v. 27, pp. 63–67 (1982)
  84. ^ A.K. Popov, A.M. Shalagin, V.M. Shalaev, V.Z. Yakhnin, Drift of gases induced by nonmonochromatic light, Applied physics, v.25, pp. 347–350 (1981)
  85. ^ V.M. Shalaev and V.Z. Yakhnin, LID sound generated by pulsed excitation in gases, Journal of Physics B: Atomic and Molecular Physics, v.20, pp. 2733–2743 (1987)
  86. ^ S. Kawata, V.M. Shalaev (editors), Tip Enhancement, Elsevier (2007)
  87. ^ S. Kawata, V.M. Shalaev (editors), Nanophotonics with Surface Plasmons, Elsevier (2007)
  88. ^ V.M. Shalaev (editor), Optical Properties of Nanostructured Random Media, Springer (2002)
  89. ^ V.M. Shalaev, M. Moskovits (editors), Nanostructured Materials: Clusters, Composites, and Thin Films, American Chemical Society (1997)
  90. ^ Prof. V. Shalaev's website: Publications
  91. ^ Prof. V. Shalaev's website: Conference Talks
  92. ^ Prof. V. Shalaev's website: Invited Lectures

January 01, 1970
vladimir, shalaev, vladimir, vlad, shalaev, born, february, 1957, distinguished, professor, electrical, computer, engineering, scientific, director, nanophotonics, birck, nanotechnology, center, purdue, university, vladimir, shalaevborn, 1957, february, 1957, . Vladimir Vlad M Shalaev born February 18 1957 is a Distinguished Professor of Electrical and Computer Engineering 13 and Scientific Director for Nanophotonics at Birck Nanotechnology Center 14 Purdue University Vladimir M ShalaevBorn 1957 02 18 February 18 1957 age 67 Krasnoyarsk RussiaCitizenshipUnited StatesAlma materKrasnoyarsk State University RussiaAwardsMax Born Award Optica 2010 1 Willis E Lamb Award for Laser Science and Quantum Optics 2 IEEE Photonics Society William Streifer Scientific Achievement Award 3 Rolf Landauer Medal ETOPIM International Association 4 UNESCO Medal for the development of nanosciences and nanotechnologies 5 Goodman Book Writing Award OSA and SPIE 6 Frank Isakson Prize for Optical Effects in Solids 7 Fellow of Professional Societies OSA 8 IEEE 9 SPIE 10 APS 11 MRS 12 Scientific careerFieldsPhysics Optics Photonics Optical nano metamaterials Plasmonics Quantum Photonics NanotechnologyInstitutionsPurdue UniversityWebsiteengineering wbr purdue wbr edu wbr shalaev wbr Contents 1 Education and career 2 Research 2 1 Optical metamaterials 2 2 Random composites 2 3 New Materials for Nanophotonics and Plasmonics 2 4 Early research 3 Awards honors memberships 4 Publications 5 ReferencesEducation and career editV Shalaev earned a Master of Science Degree in physics summa com laude in 1979 from Krasnoyarsk State University Russia and a PhD Degree in physics and mathematics in 1983 from the same university Over the course of his career Shalaev received a number of awards for his research in the fields of nanophotonics and metamaterials and he is a Fellow of several of Professional Societies see the Awards honors memberships section below Prof Shalaev has co written three and co edited four books and authored over 800 research publications in total 15 As of May 2024 his h index is 125 with the total number of citations nearing 70 000 according to Google Scholar 16 In 2017 2023 Prof Shalaev has been on the list of Highly Cited Researchers from the Web of Science Group 17 he is ranked 9 in the optics category of the Stanford list of top 2 World s highest cited scientists 18 career long out of 64 044 entries ranked 34 in the US and 58 worldwide in the field of Electronics and Electrical Engineering by Research com 19 Research editVladimir M Shalaev is recognized for his pioneering studies on linear and nonlinear optics of random nanophotonic composites that had helped to mold the research area of composite optical media 2 He also contributed to the emergence of a new field of engineered artificial materials optical metamaterials 1 2 Currently he studies new phenomena resulting from merging metamaterials and plasmonics with quantum nanophotonics 20 Optical metamaterials edit Optical metamaterials MMs are rationally designed composite nanostructured materials that exhibit unique electromagnetic properties drastically different from the properties of their constituent material components Metamaterials offer remarkable tailorability of their electromagnetic response via shape size composition and morphology of their nanoscale building blocks sometimes called meta atoms 21 Shalaev proposed and demonstrated the first optical MM that exhibits negative index of refraction and the nanostructures that show artificial magnetism across the entire visible spectrum 22 23 24 25 Here and thereafter only selected representative papers by Shalaev are cited for complete list of Shalaev s publications visit his website 26 He made important contributions to active nonlinear and tunable metamaterials which enable new ways of controlling light and accessing new regimes of enhanced light matter interactions 27 28 29 30 Shalaev also experimentally realized negative refractive index MMs where optical gain medium is used to compensate for light absorption optical loss 29 He made significant contributions to the so called Transformation Optics 31 specifically on optical concentrators and invisibility cloaks 32 33 34 35 In collaboration with Noginov Shalaev demonstrated the smallest 40 nm nanolaser operating in the visible spectral range 36 37 Shalaev also made seminal contributions to two dimensional flat metamaterials metasurfaces 38 that introduce abrupt changes to the phase of light at a single interface via coupling to nanoscale optical antennas 39 40 41 42 43 He realized extremely compact flat lens 41 ultra thin hologram 42 and record small circular dichroism spectrometer 43 compatible with planar optical circuitry MM designs developed by Shalaev are now broadly employed for research in sub wavelength optical imaging nanoscale lasers and novel sensors 38 44 Shalaev s work had a strong impact on the whole field of metamaterials 1 2 3 Three of Shalaev s papers Refs 22 23 and 32 remain among the top 50 most cited out of over 750 000 papers included in the ISI Web of Science OPTICS category since 2005 as of January 2021 45 Random composites edit Shalaev made pioneering contributions to the area of random optical media including fractal and percolation composites 2 46 47 48 49 50 51 52 53 54 55 56 He predicted the highly localized optical modes hot spots for fractals and percolating films which were later experimentally demonstrated by Shalaev in collaboration with the Moskovits and Boccara groups 52 53 Furthermore he showed that the hot spots in fractal and percolation random composites are related to localization of surface plasmons 46 56 These localized surface plasmon modes in random systems are sometimes referred to as Shalaev s hot spots see e g 57 This research on random composites stemmed from the early studies on fractals performed by Shalaev in collaboration with M I Stockman 58 59 60 61 62 63 a theory of random metal dielectric films was worked out in collaboration with A K Sarychev 47 49 50 54 Shalaev also developed fundamental theories of surface enhanced Raman scattering SERS and strongly enhanced optical nonlinearities in fractals and percolation systems and led experimental studies aimed to verify the developed theories 46 56 60 64 65 Shalaev also predicted that nonlinear phenomena in random systems can be enhanced not only because of the high local fields in hot spots but also due to the rapid nanoscale spatial variation of these fields in the vicinity of hot spots which serves as a source of additional momentum and thus enables indirect electronic transitions 65 Shalaev s contributions to the optics and plasmonics of random media 46 56 helped to transform those concepts into the area of optical metamaterials 22 25 27 36 Owing to the theory and experimental approaches developed in the area of random composites optical metamaterials have quickly become a mature research field surprisingly rich in new physics 24 4 Shalaev s impact on the development of both fields is in identifying the strong synergy and close connection between these two frontier fields of optics that unlock an entirely new set of physical properties 4 New Materials for Nanophotonics and Plasmonics edit Random composites and metamaterials provide a unique opportunity to tailor their optical properties via shape size and composition of their nanoscale building blocks which often require metals to confine light down to the nanometer scale via the excitation of surface plasmons 46 30 To enable practical applications of plasmonics Shalaev in collaboration with A Boltasseva 66 developed novel plasmonic materials namely transition metal nitrides and transparent conducting oxides TCOs paving the way to durable low loss and CMOS compatible plasmonic and nanophotonic devices 67 68 69 70 71 72 73 The proposed plasmonic ceramics operating at high temperatures can offer solutions to highly efficient energy conversion photocatalysis and data storage technologies 69 73 In collaboration with the Faccio group 74 Shalaev demonstrated ultrafast strongly enhanced nonlinear responses in TCOs that possess an extremely low close to zero linear refractive index the so called epsilon near zero regime 75 76 77 78 79 Independently the Boyd group obtained equally remarkable results in a TCO material 80 demonstrating that low index TCOs hold a promise for novel nonlinear optics Early research edit Shalaev s PhD work supervised by Prof A K Popov and early research involved theoretical analysis of resonant interaction of laser radiation with gaseous media in particular i Doppler free multi photon processes in strong optical fields and their applications in nonlinear optics 81 spectroscopy 82 and laser physics 83 as well as ii the newly discovered then phenomenon of light induced drift of gases 84 85 Awards honors memberships editRecognized as Highly Cited Researcher by the Web of Science Group in 2017 2022 17 Ranked 9 in the optics category of the Stanford list of top 2 World s highest cited scientists 18 career long out of 64 044 entries Ranked 28 in electronics and electrical engineering among top USA researchers according to Research com The 2020 Frank Isakson Prize for Optical Effects in Solids 7 The Optical Society of America Max Born Award 2010 1 The Willis E Lamb Award for Laser Science and Quantum Optics 2010 2 IEEE Photonics Society William Streifer Scientific Achievement Award 2015 3 Rolf Landauer Medal of the ETOPIM Electrical Transport and Optical Properties of Inhomogeneous Media International Association 2015 4 The 2012 Nanotechnology Award from UNESCO 5 The 2014 Goodman Book Award from OSA and SPIE 6 Honorary Doctorate from University of Southern Denmark 2015 The 2006 Top 50 Nano Technology Award Winner for Nanorod Material The 2009 McCoy Award Purdue University s highest honor for scientific achievement Fellow of the Materials Research Society MRS 12 since 2015 Fellow of the Institute of Electrical and Electronics Engineers IEEE 9 since 2010 Fellow of the American Physical Society APS 11 since 2002 Fellow of the Optical Society of America OSA 8 since 2003 Fellow of the International Society for Optical Engineering SPIE 10 since 2005 General co Chair for 2011 and Program co Chair 2009 of CLEO QELS conferences Chair of the OSA Technical Group Photonic Metamaterials 2004 2010 Reviewing Editor for Science Science Magazine Co Editor of Applied Physics B Lasers and Optics 2006 2013 Topical Editor for Journal of Optical Society of America B 2005 2011 Editorial Board Member for Nanophotonics journal since 2012 Editorial Advisory Board Member for Laser and Photonics Reviews since 2008Publications editProf Shalaev co authored three 24 48 50 and co edited four 86 87 88 89 books in the area of his scientific expertise According to Shalaev s website 90 over the course of his career he contributed 30 invited chapters to various scientific anthologies and published a number of invited review articles over 800 publications in total He made over 500 invited presentations at International Conferences and leading research centers including a number of plenary and keynote talks 91 92 References edit a b c d 2010 Optical Society of America Max Born Award a b c d e f 2010 Willis E Lamb Award for Laser Science and Quantum Optics a b c 2015 IEEE Photonics Society William Streifer Scientific Achievement Award a b c d 2015 Rolf Landauer International ETOPIM Association Medal a b 2012 UNESCO Medal for the Development of Nanosciences and Nanotechnologies a b 2014 Joseph W Goodman Book Writing Award a b 2020 Frank Isakson Prize for Optical Effects in Solids a b 2003 OSA Fellows a b IEEE Fellows Directory a b Complete List of SPIE Fellows a b APS Fellow Archive a b List of MRS Fellows People School of Electrical and Computer Engineering Purdue University Birck Nanotechnology Center Faculty V Shalaev s publication list Shalaev h index and citations Google Scholar a b V Shalaev webofscience com a b Updated science wide author databases of standardized citation indicators September 2022 Research com Best Scientists Electronics and Electrical Engineering S I Bogdanov A Boltasseva V M Shalaev Overcoming quantum decoherence with plasmonics Science v 364 no 6440 pp 532 533 2019 N Meinzer W L Barnes amp I R Hooper Plasmonic meta atoms and metasurfaces N Meinzer William L Barnes amp I R Hooper Nature Photonics v 8 pp 889 898 2014 a b c V M Shalaev Optical Negative Index Metamaterials Nature photonics v 1 pp 41 48 2007 a b V M Shalaev W Cai U K Chettiar H K Yuan A K Sarychev V P Drachev and A V Kildishev Negative Index of Refraction in Optical Metamaterials Optics Letters v 30 pp 3356 3358 2005 a b c W Cai V M Shalaev Optical Metamaterials Fundamentals and Applications Springer Verlag New York 2010 a b W Cai U K Chettiar H K Yuan V C de Silva A V Kildishev V P Drachev and V M Shalaev Metamagnetics with rainbow colors Optics Express v 15 pp 3333 3341 2007 Prof V Shalaev Purdue University Electrical amp Computer Engineering a b A K Popov and V M Shalaev Negative index metamaterials second harmonic generation Manley Rowe relations and parametric amplification Applied Physics B v 84 pp 131 37 2006 S Xiao U K Chettiar A V Kildishev V P Drachev I C Khoo and V M Shalaev Tunable magnetic response of metamaterials Applied Physics Letters v 95 p 033114 2009 a b S Xiao V P Drachev A V Kildishev X Ni U K Chettiar H K Yuan and V M Shalaev Loss free and active optical negative index metamaterials Nature v 466 pp 735 738 2010 a b O Hess J B Pendry S A Maier R F Oulton J M Hamm and K L Tsakmakidis Active nanoplasmonic metamaterials Nature Materials v 11 pp 573 584 2012 H Chen C T Chan and P Sheng Transformation optics and metamaterials Nature Materials v 9 pp 387 396 2010 a b W Cai U K Chettiar A V Kildishev and V M Shalaev Optical cloaking with metamaterials Nature Photonics v 1 pp 224 227 2007 I I Smolyaninov V N Smolyaninova A V Kildishev and V M Shalaev Anisotropic Metamaterials Emulated by Tapered Waveguides Application to Optical Cloaking Physical Review Letters v 102 p 213901 2009 V M Shalaev Transforming Light Science v 322 pp 384 386 2008 A V Kildishev and V M Shalaev Engineering space for light via transformation optics Optics Letters v 33 pp 43 45 2008 a b M A Noginov G Zhu A M Belgrave R Bakker V M Shalaev E E Narimanov S Stout E Herz T Suteewong and U Wiesner Demonstration of a spaser based nanolaser Nature v 460 pp 1110 1112 2009 M Premaratne and M I Stockman Theory and Technology of SPASERs Advances In Optics And Photonics v 9 pp 79 128 2017 a b N Yu and F Capasso Optical Metasurfaces and Prospect of Their Applications Including Fiber Optics Journal Of Lightwave Technology v 33 pp 2344 2358 2015 X Ni N K Emani A V Kildishev A Boltasseva and V M Shalaev Broadband light bending with plasmonic nanoantennas Science v 335 pp 427 2012 A V Kildishev A Boltasseva and V M Shalaev Planar photonics with metasurfaces Science v 339 p 1232009 2013 a b X Ni S Ishii A V Kildishev and V M Shalaev Ultra thin planar Babinet inverted plasmonic metalenses Light Science amp Applications v 2 p e72 2013 a b X Ni A V Kildishev and V M Shalaev Metasurface holograms for visible light Nature Communications v 4 pp 1 6 2013 a b A Shaltout J Liu A Kildishev and V Shalaev Photonic spin Hall effect in gap plasmon metasurfaces for on chip chiroptical spectroscopy Optica v 2 pp 860 863 2015 C Deeb J L Pelouard Plasmon lasers coherent nanoscopic light sources Physical Chemistry Chemical Physics v 19 pp 29731 29741 2017 Web of Science Core Collection Search Results a b c d e V M Shalaev Electromagnetic Properties of Small Particle Composites Physics Reports v 272 pp 61 137 1996 a b V M Shalaev and A K Sarychev Nonlinear optics of random metal dielectric films Physical Review B v 57 pp 13265 13288 1998 a b V M Shalaev Nonlinear Optics of Random Media Fractal Composites and Metal Dielectric Films Springer 2000 a b A K Sarychev V M Shalaev Electromagnetic field fluctuations and optical nonlinearities in metal dielectric composites Physics Reports v 335 pp 275 371 2000 a b c A K Sarychev V M Shalaev Electrodynamics of Metamaterials World Scientific 2007 M I Stockman V M Shalaev M Moskovits R Botet T F George Enhanced Raman scattering by fractal clusters Scale invariant theory Physical Review B v 46 pp 2821 2830 1992 a b D P Tsai J Kovacs Zh Wang M Moskovits V M Shalaev J S Suh and R Botet Photon Scanning Tunneling Microscopy Images of Optical Excitations of Fractal Metal Colloid Clusters Physical Review Letters v 72 pp 4149 4152 1994 a b S Gresillon L Aigouy A C Boccara J C Rivoal X Quelin C Desmarest P Gadenne V A Shubin A K Sarychev and V M Shalaev Experimental Observation of Localized Optical Excitations in Random Metal Dielectric Films Physical Review Letters v 82 pp 4520 4523 1999 a b A K Sarychev V A Shubin and V M Shalaev Anderson localization of surface plasmons and nonlinear optics of metal dielectric composites Physical Review B v 60 pp 16389 16408 1999 V P Safonov V M Shalaev V A Markel Yu E Danilova N N Lepeshkin W Kim S G Rautian and R L Armstrong Spectral Dependence of Selective Photomodification in Fractal Aggregates of Colloidal Particles Physical Review Letters v 80 pp 1102 1105 1998 a b c d W Kim V P Safonov V M Shalaev and R L Armstrong Fractals in Microcavities Giant Coupled Multiplicative Enhancement of Optical Responses Physical Review Letters v 82 pp 4811 4814 1999 A Otto On the significance of Shalaev s hot spots in ensemble and single molecule SERS by adsorbates on metallic films at the percolation threshold J Raman Spectroscopy v 37 pp 937 947 2006 V M Shalaev M I Stockman Fractals optical susceptibility and giant Raman scattering Zeitschrift fur Physik D Atoms Molecules and Clusters v 10 pp 71 79 1988 A V Butenko V M Shalaev M I Stockman Fractals giant impurity nonlinearities in optics of fractal clusters Zeitschrift fur Physik D Atoms Molecules and Clusters v 10 pp 81 92 1988 a b S G Rautian V P Safonov P A Chubakov V M Shalaev M I Shtockman Surface enhanced parametric scattering of light by silver clusters JETP Lett v 47 pp 243 246 1988 translated from Zh Eksp Teor Fiz v 47 pp 20 203 1988 A V Butenko P A Chubakov Yu E Danilova S V Karpov A K Popov S G Rautian V P Safonov V V Slabko V M Shalaev M I Stockman Nonlinear optics of metal fractal clusters Zeitschrift fur Physik D Atoms Molecules and Clusters v 990 pp 283 289 1990 V M Shalaev R Botet R Jullien Resonant light scattering by fractal clusters Physical Review B v 44 pp 12216 12225 1991 V M Shalaev M I Stockman and R Botet Resonant excitations and nonlinear optics of fractals Physica A v 185 pp 181 186 1992 M Breit V A Podolskiy S Gresillon G von Plessen J Feldmann J C Rivoal P Gadenne A K Sarychev and Vladimir M Shalaev Experimental observation of percolation enhanced non linear light scattering from semicontinuous metal films Physical Review B v 64 p 125106 2001 a b V M Shalaev C Douketis T Haslett T Stuckless and M Moskovits Two photon electron emission from smooth and rough metal films in the threshold region Physical Review B v 53 p 11193 1996 Prof A Boltasseva s research group site P R West S Ishii G V Naik N K Emani V M Shalaev and A Boltasseva Searching for better plasmonic materials Laser amp Photonics Reviews v 4 pp 795 808 2010 G V Naik V M Shalaev and A Boltasseva Alternative Plasmonic Materials Beyond Gold and Silver Advanced Materials v 25 pp 3264 3294 2013 a b U Guler A Boltasseva and V M Shalaev Refractory plasmonics Science v 344 pp 263 264 2014 U Guler V M Shalaev A Boltasseva Nanoparticle Plasmonics Going Practical with Transition Metal Nitrides Materials Today v 18 pp 227 237 2014 U Guler A Kildishev A Boltasseva and V M Shalaev Plasmonics on the slope of enlightenment the role of transition metal nitrides Faraday Discussions v 178 pp 71 86 2015 A Boltasseva and V M Shalaev All that glitters need not be gold Science v 347 pp 1308 1310 2015 a b A Naldoni U Guler Zh Wang M Marelli F Malara X Meng A V Kildishev A Boltasseva V M Shalaev Broadband Hot Electron Collection for Solar Water Splitting with Plasmonic Titanium Nitride Advanced Optical Materials v 5 p 1601031 2017 Prof D Faccio group Heriot Watt University UK L Caspani R P M Kaipurath M Clerici M Ferrera T Roger A Di Falco J Kim N Kinsey V M Shalaev A Boltasseva D Faccio Enhanced Nonlinear Refractive Index in e Near Zero Materials Physical Review Letters v 116 p 233901 2016 M Clerici N Kinsey C DeVault J Kim E G Carnemolla L Caspani A Shaltout D Faccio V Shalaev A Boltasseva M Ferrera Controlling hybrid nonlinearities in transparent conducting oxides via two colour excitation Nature Communications v 8 p 15829 2017 S Vezzoli V Bruno C DeVault T Roger V M Shalaev A Boltasseva M Ferrera M Clerici A Dubietis and D Faccio1 Optical time reversal from time dependent epsilon near zero media Physical Review Letters v 120 p 043902 2018 V Bruno C DeVault S Vezzoli D Shah S Maier A Jacassi S Minguzzi T Huq Z Kudyshev S Saha A Boltasseva M Ferrera M Clerici D Faccio R Sapienza V Shalaev Negative refraction in time varying strongly coupled plasmonic antenna ENZ systems Physical Review Letters 124 4 043902 January 30 2020 N Kinsey C DeVault A Boltasseva V M Shalaev Near zero index materials for photonics Nature Reviews Materials v 4 pp 742 760 2019 M Z Alam I De Leon R W Boyd Large optical nonlinearity of indium tin oxide in its epsilon near zero region Science v 352 pp 795 797 2016 A K Popov V M Shalaev Doppler free transitions induced by strong double frequency optical excitations Optics Communications v 35 pp 189 193 1980 A K Popov V M Shalaev Doppler free spectroscopy and wave front conjugation by four wave mixing of nonmonochromatic waves Applied Physics v 21 pp 93 94 1980 A K Popov V M Shalaev Unidirectional Doppler Free Gain And Generation In Optically Pumped Lasers Applied Physics B v 27 pp 63 67 1982 A K Popov A M Shalagin V M Shalaev V Z Yakhnin Drift of gases induced by nonmonochromatic light Applied physics v 25 pp 347 350 1981 V M Shalaev and V Z Yakhnin LID sound generated by pulsed excitation in gases Journal of Physics B Atomic and Molecular Physics v 20 pp 2733 2743 1987 S Kawata V M Shalaev editors Tip Enhancement Elsevier 2007 S Kawata V M Shalaev editors Nanophotonics with Surface Plasmons Elsevier 2007 V M Shalaev editor Optical Properties of Nanostructured Random Media Springer 2002 V M Shalaev M Moskovits editors Nanostructured Materials Clusters Composites and Thin Films American Chemical Society 1997 Prof V Shalaev s website Publications Prof V Shalaev s website Conference Talks Prof V Shalaev s website Invited Lectures Retrieved from https en wikipedia org w index php title Vladimir Shalaev amp oldid 1224502890, wikipedia, wiki, book, books, library,

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