RSS feeds
РусскийEnglish
Issue 4, 2024
Volume year page
Issues Authors PACS Subscription For authors

Issues

 / 

2010

 / 

March

  

Reviews of topical problems


Surface states in photonic crystals

 a,  a,  a,  b
a Institute for Theoretical and Applied Electrodynamics, Russian Academy of Sciences, ul. Izhorskaya 13/19, Moscow, 127412, Russian Federation
b Department of Physics, Queens College of the City University of New York, Flushing, New York, USA

Propagation of surface electromagnetic waves along photonic crystal (PC) boundaries is examined. It is shown that in a number of cases these waves are backward. The nature of the surface electromagnetic states, localized at the PC boundary, is discussed; these states transfer no energy along the boundary (their tangential wave number is zero). An analogy with the well-known Tamm and Shockley surface states in solid state physics is drawn. It is shown that in the case of PC both types of states can be considered as the Tamm ones. Experimental results on the observation of the surface states are presented. A system using an external magnetic field to control a surface state is considered.

Fulltext pdf (682 KB)
Fulltext is also available at DOI: 10.3367/UFNe.0180.201003b.0249
PACS: 41.20.Jb, 42.70.Qs, 73.20.−r (all)
DOI: 10.3367/UFNe.0180.201003b.0249
URL: https://ufn.ru/en/articles/2010/3/b/
000280435100002
2-s2.0-77954801596
2010PhyU...53..243V
Citation: Vinogradov A P, Dorofeenko A V, Merzlikin A M, Lisyansky A A "Surface states in photonic crystals" Phys. Usp. 53 243–256 (2010)
BibTexBibNote ® (generic)BibNote ® (RIS)MedlineRefWorks

Оригинал: Виноградов А П, Дорофеенко А В, Мерзликин А М, Лисянский А А «Поверхностные состояния в фотонных кристаллах» УФН 180 249–263 (2010); DOI: 10.3367/UFNr.0180.201003b.0249

References (85) Cited by (132) ↓ Similar articles (20)

  1. Goyal A K, Divyanshu D, Massoud Y Sci Rep 14 (1) (2024)
  2. Nakata Y, Nakanishi T et al Phys. Rev. B 108 (17) (2023)
  3. Obradov M, Jakšić Zoran et al Coatings 13 198 (2023)
  4. Rudakova N V, Bikbaev R G et al Photonics 10 1391 (2023)
  5. Khattou S, Rezzouk Ya et al Phys. Rev. B 107 (12) (2023)
  6. Mudi R, Mallik S et al Optical Materials 140 113848 (2023)
  7. Davydov V N Graphene And 2D Mater 8 81 (2023)
  8. Khanin S D, Vanin A I et al Tech. Phys. 68 S7 (2023)
  9. Tian J, Tan Q Y et al Nat Commun 14 (1) (2023)
  10. Goyal A K, Divyanshu D, Massoud Y 2023 IEEE 23rd International Conference on Nanotechnology (NANO), (2023) p. 878
  11. Goyal A K, Pradhan K P, Massoud Y 2022 IEEE 22nd International Conference on Nanotechnology (NANO), (2022) p. 257
  12. Mikhailova T, Tomilin S et al Opt. Mater. Express 12 685 (2022)
  13. Farhadi P, Rezaei B Optik 265 169538 (2022)
  14. Deng W-M, Chen Z-M et al Light Sci Appl 11 (1) (2022)
  15. Rudakova N V, Bikbaev R G et al Nanomaterials 12 234 (2022)
  16. Goyal A K, Kumar A, Massoud Y Photonics 9 324 (2022)
  17. Bikbaev R, Vetrov S et al Photonics 9 786 (2022)
  18. Gonçalves M R Front. Nanotechnol. 3 (2021)
  19. Bashiri J, Rezaei B Photonics And Nanostructures - Fundamentals And Applications 43 100891 (2021)
  20. Avdeeva A Yu, Vetrov S Ya, Timofeev I V J. Opt. Soc. Am. B 38 1792 (2021)
  21. Kumar M, Prasad S Materials Today Communications 29 102889 (2021)
  22. Palatnik A, Sudzius M et al 10 2459 (2021)
  23. Bezus E A, Kadomina E A et al J. Phys.: Conf. Ser. 2015 012016 (2021)
  24. Bikbaev R G, Maksimov D N et al Opt. Express 29 4672 (2021)
  25. Akjouj A, Dobrzyński L et al Photonics (2021) p. 439
  26. Minin O V, Minin I V The Photonic Hook SpringerBriefs In Physics Chapter 4 (2021) p. 55
  27. Downing Ch A, Martín-Moreno L 10 513 (2020)
  28. Avdeeva A Yu, Vetrov S Ya et al Materials 13 3255 (2020)
  29. Bianchi N J, Kahn L M J. Opt. 22 065101 (2020)
  30. Gulyaev Yu V, Tarasenko S V, Shavrov V G Phys.-Usp. 63 872 (2020)
  31. Bykov D A, Bezus E A, Doskolovich L L 9 83 (2020)
  32. Davidovich M V Opt. Spectrosc. 128 1379 (2020)
  33. Chermoshentsev D A, Anikin E V et al 9 4785 (2020)
  34. Inogamov N A, Petrov Yu V et al High Temp 58 632 (2020)
  35. Skripal A V, Ponomarev D V, Komarov A A IEEE Trans. Microwave Theory Techn. 68 5115 (2020)
  36. Nakata Y, Ito Y et al Phys. Rev. Lett. 124 (7) (2020)
  37. 415 (2019)
  38. Boginskaya I A, Nechepurenko I A et al J Raman Spectroscopy 50 1452 (2019)
  39. Rudakova N V, Timofeev I V et al Crystals 9 502 (2019)
  40. Borovkova O V, Spitzer F et al 8 287 (2019)
  41. Rybin M V, Limonov M F Phys.-Usp. 62 823 (2019)
  42. Gonzalez-Valencia E, Herrera R A, Torres P Opt. Express 27 8236 (2019)
  43. Averkov Yu O, Prokopenko Yu V, Yakovenko V M Tech. Phys. 64 1 (2019)
  44. Mikhailova T V, Lyashko S D et al J. Phys.: Conf. Ser. 1389 012103 (2019)
  45. Occhicone A, Sinibaldi G et al 114 (13) (2019)
  46. Bashiri J, Rezaei B et al J. Opt. Soc. Am. B 36 2106 (2019)
  47. Bakman A, Veksler H, Fishman Sh Eur. Phys. J. B 92 (10) (2019)
  48. Yang Q, Zhang Ch et al Nano Energy 48 161 (2018)
  49. Mikhailova T, Shaposhnikov A et al EPJ Web Conf. 185 02016 (2018)
  50. Yudina D, Ivzhenko L 2018 IEEE 17th International Conference on Mathematical Methods in Electromagnetic Theory (MMET), (2018) p. 160
  51. Bezus E, Bykov D, Doskolovich L Computer Optics 42 22 (2018)
  52. Usanov D A, Nikitov S A et al Tech. Phys. 63 1015 (2018)
  53. Ignatov A I, Merzlikin A M J. Opt. Soc. Am. B 35 308 (2018)
  54. Pyatnov M, Timofeev I et al Photonics 5 30 (2018)
  55. Ignatov A I, Merzlikin A M Optics Communications 410 83 (2018)
  56. Zhou Zh, Xin J et al Applied Sciences 8 1420 (2018)
  57. Arakelian S M, Osipov A V et al Bull. Russ. Acad. Sci. Phys. 81 1401 (2017)
  58. Baghbadorani H K, Barvestani J, Entezar S R Appl. Opt. 56 462 (2017)
  59. Lapine M Phys. Status Solidi B 254 1600462 (2017)
  60. Vetrov S Ya, Pankin P S, Timofeev I V Phys. Wave Phen. 25 170 (2017)
  61. Takayama O, Shkondin E et al ACS Photonics 4 2899 (2017)
  62. (Metamaterials XI) Vol. Metamaterials XI On-chip near-wavelength diffraction gratings for surface electromagnetic waves VladimírKuzmiakPeterMarkosTomaszSzoplikEvgeni A.BezusVladimir V.PodlipnovAndrey A.MorozovLeonid L.Doskolovich10227 (2017) p. 1022709
  63. Boginskaya I A, Afanasiev K N et al 2017 Progress In Electromagnetics Research Symposium - Spring (PIERS), (2017) p. 3094
  64. Pyatnov M V, Vetrov S Ya, Timofeev I V J. Opt. Soc. Am. B 34 2011 (2017)
  65. Tarasenko S V, Shavrov V G Jetp Lett. 106 103 (2017)
  66. Bikbaev R G, Vetrov S Ya, Timofeev I V J. Opt. Soc. Am. B 34 2198 (2017)
  67. Takayama O, Bogdanov A A, Lavrinenko A V J. Phys.: Condens. Matter 29 463001 (2017)
  68. Vetrov S Ya, Bikbaev R G, Timofeev I V Optics Communications 395 275 (2017)
  69. Rychły J, Kłos J W J. Phys. D: Appl. Phys. 50 164004 (2017)
  70. Pyatnov M V, Vetrov S Ya, Timofeev I V Opt. Spectrosc. 123 189 (2017)
  71. Vetrov S Ya, Bikbaev R G et al J. Opt. 19 085103 (2017)
  72. Mikhailova T V, Lyashko S D et al J. Phys.: Conf. Ser. 917 062053 (2017)
  73. Hajian H, Caglayan H, Ozbay E 121 (3) (2017)
  74. Bikbaev R G, Vetrov S Ya, Timofeev I V J. Opt. 19 015104 (2017)
  75. Yudina D, Ivzhenko L 2017 IEEE International Young Scientists Forum on Applied Physics and Engineering (YSF), (2017) p. 307
  76. Ignatov A I, Merzlikin A M et al Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XV, (2017) p. 81
  77. Pyatnov M V, Vetrov S Ya, Timofeev I V Liquid Crystals 44 674 (2017)
  78. Timofeev I V, Pankin P S et al Crystals 7 113 (2017)
  79. Vetrov S Ya, Pankin P S, Timofeev I V J. Opt. 18 065106 (2016)
  80. Furs A N J. Opt. Technol. 83 81 (2016)
  81. Kadomina E A, Bezus E A, Doskolovich L L Tech. Phys. 61 1389 (2016)
  82. Timofeev I V, Vetrov S Ya Jetp Lett. 104 380 (2016)
  83. Korovin A V, Romanov S G Phys. Rev. B 93 (11) (2016)
  84. Vetrov S Ya, Pyatnov M V, Timofeev I V J. Opt. 18 015103 (2016)
  85. (Photonic Crystal Materials and Devices XII) Vol. Photonic Crystal Materials and Devices XIIUnconventional optical Tamm defect states in metal-terminated opal photonic crystalsDarioGeraceGabrielLozanoChristelleMonatSergei G.RomanovAlexander V.KorovinSergei G.Romanov9885 (2016) p. 98851M
  86. Savchenko A S, Tarasenko A S et al Bull. Russ. Acad. Sci. Phys. 80 529 (2016)
  87. Sylgacheva D A, Khokhlov N E et al J. Exp. Theor. Phys. 123 737 (2016)
  88. Pankin P S, Vetrov S Ya, Timofeev I V 2016 Progress in Electromagnetic Research Symposium (PIERS), (2016) p. 4571
  89. Anopchenko A, Occhicone A et al Opt. Express 24 7728 (2016)
  90. Beletskii N, Borysenko S RADIOFIZ. ELEKTRON. 21 22 (2016)
  91. Golenitskii K  Yu, Koshelev K  L, Bogdanov A  A Phys. Rev. A 94 (4) (2016)
  92. Sylgacheva D A, Khokhlov N E et al J. Phys.: Conf. Ser. 714 012016 (2016)
  93. Khokhlov N E, Prokopov A R et al J. Phys. D: Appl. Phys. 48 095001 (2015)
  94. Doskolovich L L, Bezus E A, Bykov D A Opt. Express 23 27034 (2015)
  95. Manenkov A B J. Commun. Technol. Electron. 60 321 (2015)
  96. Beletskii N, Borysenko S, Gvozdev N RADIOFIZ. ELEKTRON. 20 62 (2015)
  97. Gorelik V S, Ivicheva S N et al Inorg Mater 51 525 (2015)
  98. Klimov V V, Treshin I V et al Phys. Rev. A 92 (6) (2015)
  99. Xiong X Y Z, Meng L L et al IEEE Trans. Antennas Propagat. 63 69 (2015)
  100. Zaitsev K I, Gorelik V S et al Bull. Lebedev Phys. Inst. 42 48 (2015)
  101. Bezus E A, Doskolovich L L Opt. Spectrosc. 119 784 (2015)
  102. Gorelik V S, Zaytsev K I et al Inorg Mater 51 419 (2015)
  103. Nechepurenko I A, Dorofeenko A V et al Moscow Univ. Chem. Bull. 70 117 (2015)
  104. Romanov S G Organic and Hybrid Photonic Crystals Chapter 20 (2015) p. 451
  105. Bezus E A, Doskolovich L L, Soifer V A Opt. Lett. 40 4935 (2015)
  106. Averkov Yu O, Tarapov S I et al J. Exp. Theor. Phys. 120 702 (2015)
  107. (Terahertz Physics, Devices, and Systems VIII: Advanced Applications in Industry and Defense) Vol. Terahertz Physics, Devices, and Systems VIII: Advanced Applications in Industry and DefenseCoherent phenomena in terahertz 2D plasmonic structures: strong coupling, plasmonic crystals, and induced transparency by coupling of localized modesMehdi F.AnwarThomas W.CroweTariqManzurGregory C.DyerGregory R.AizinS. JamesAllenAlbert D.GrineDonBethkeJohn L.RenoEric A.Shaner9102 (2014) p. 91020L
  108. Smirnova D, Buslaev P et al Phys. Rev. B 89 (24) (2014)
  109. Zyablovsky A A, Vinogradov A P et al Uspekhi Fizicheskikh Nauk 184 1177 (2014) [Zyablovsky A A, Vinogradov A P et al Phys.-Usp. 57 1063 (2014)]
  110. Poshakinskiy A  V, Poddubny A  N et al Phys. Rev. Lett. 112 (10) (2014)
  111. Bezus E A, Doskolovich L L et al Jetp Lett. 99 63 (2014)
  112. Latyshev Yu I, Orlov A P et al Sci Rep 4 (1) (2014)
  113. Vetrov S Ya, Pyatnov M V, Timofeev I V Opt. Lett. 39 2743 (2014)
  114. Averkov Yu O, Tarapov S I et al 40 667 (2014)
  115. Melentiev P, Afanasiev A, Balykin V Phys. Rev. A 88 (5) (2013)
  116. Tarapov S I, Belozorov D P 2013 International Kharkov Symposium on Physics and Engineering of Microwaves, Millimeter and Submillimeter Waves, (2013) p. 13
  117. He Ch, Sun X-Ch et al Opt. Express 21 28933 (2013)
  118. Vetrov S Ya, Bikbaev R G, Timofeev I V J. Exp. Theor. Phys. 117 988 (2013)
  119. Li G V, Astrova E V et al Physica Rapid Research Ltrs 7 481 (2013)
  120. Vojtíšek P, Richter I et al EPJ Web Of Conferences 48 00030 (2013)
  121. Timofeev I V, Arkhipkin V G et al Opt. Mater. Express 3 496 (2013)
  122. Treshin I V, Klimov V V et al Phys. Rev. A 88 (2) (2013)
  123. Averkov Yu O, Yakovenko V M Phys. Solid State 54 630 (2012)
  124. Bulgakov A A, Fedorin I V Phys. Solid State 54 1566 (2012)
  125. Tarapov S I, Belozorov D P 38 603 (2012)
  126. Dorofeenko A V, Zyablovsky A A et al Uspekhi Fizicheskikh Nauk 182 1157 (2012)
  127. Savchenko A S, Tarasenko A S et al Dokl. Phys. 57 387 (2012)
  128. Dyakov S A, Baldycheva A et al Phys. Rev. B 86 (11) (2012)
  129. Xie Q, Lee Ch Phys. Rev. A 85 (6) (2012)
  130. Iorsh I, Orlov A et al 99 (15) (2011)
  131. Tserkezis C, Stefanou N et al Phys. Rev. B 84 (11) (2011)
  132. Furs A N J. Opt. 13 055103 (2011)
© 1918–2024 Uspekhi Fizicheskikh Nauk
Email: ufn@ufn.ru Editorial office contacts About the journal Terms and conditions