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Issue 3, 2026
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Issues

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1997

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February

  

Reviews of topical problems


Magnons, magnetic polaritons, magnetostatic waves

 a,  b,  b
a P.L. Kapitza Institute for Physical Problems, Russian Academy of Sciences, ul. Kosygina 2, Moscow, 119334, Russian Federation
b Lomonosov Moscow State University, Vorobevy Gory, Moscow, 119991, Russian Federation

Electrodynamical properties of magnetically ordered media are analyzed theoretically. Two types of magnetic materials, namely ferromagnets and antiferromagnets, are considered and the effect of the magnetic subsystem on the properties of the host metal are discussed. Various types of elementary excitations, such as magnetic polaritons, magnetostatic waves, and magnons, are examined within the conventional quasiparticle framework. The dispersion of the quasiparticles as a function of the relation between the characteristic frequencies of electrical and magnetic nature is described over a wide range of frequencies. Particular attention is given to the statistical thermodynamics and kinetics of the magnetic materials. The possibility of Bose-Einstein condensation in a magnon gas is analyzed and the kinetic theory of electron-assisted magnetostatic wave damping in a ferromagnetic metal is developed. The dispersion of surface polaritons is examined in detail. Examples of solutions of spatially non-uniform problems are discussed with allowance made for spatial dispersion, which show this latter to be of particular importance in antiferromagnets.

Fulltext pdf (614 KB)
Fulltext is also available at DOI: 10.1070/PU1997v040n02ABEH000194
PACS: 71.36.+c, 75.30.Ds, 76.50.+g (all)
DOI: 10.1070/PU1997v040n02ABEH000194
URL: https://ufn.ru/en/articles/1997/2/d/
A1997WT28000004
Citation: Kaganov M I, Pustyl’nik N B, Shalaeva T I "Magnons, magnetic polaritons, magnetostatic waves" Phys. Usp. 40 181–224 (1997)
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Оригинал: Каганов М И, Пустыльник Н Б, Шалаева Т И «Магноны, магнитные поляритоны, магнитостатические волны» УФН 167 191–237 (1997); DOI: 10.3367/UFNr.0167.199702d.0191

References (31) Cited by (86) ↓ Similar articles (20)

  1. Kühn F, Schweizer M R et al Phys. Rev. B 113 (1) (2026)
  2. Chen J, Yu H et al Physics Reports 1176 1 (2026)
  3. Dai Zh, Cheng B et al Progress In Quantum Electronics 103 100585 (2025)
  4. Litinskaya M Encyclopedia of Condensed Matter Physics (2024) p. 497
  5. R T V, Evlyukhin A B J. Phys. D: Appl. Phys. 57 (13) 135005 (2024)
  6. Dantas L Q, Vasconcelos M S et al J. Phys.: Condens. Matter 35 (37) 375801 (2023)
  7. Zheng Y, Chen J et al J. Opt. Soc. Am. B 40 (11) 2815 (2023)
  8. Frey P, Vasyuchka V I et al Journal Of Magnetism And Magnetic Materials 545 168628 (2022)
  9. Yuan H Y, Cao Yu et al Physics Reports 965 1 (2022)
  10. Hale N, Simonsen I et al Phys. Rev. B 105 (10) (2022)
  11. Pirro P, Vasyuchka V I et al Nat Rev Mater 6 (12) 1114 (2021)
  12. Kamenetskii E Topics In Applied Physics Vol. Chirality, Magnetism and MagnetoelectricityMagnetoelectric Near Fields138 Chapter 19 (2021) p. 523
  13. Han N, Liu J et al Annalen Der Physik 532 (8) (2020)
  14. Eroshenko Yu N Phys.-Usp. 63 (10) 1048 (2020)
  15. Tuz V R, Fesenko V I Journal of Applied Physics 128 (1) (2020)
  16. Kamenetskii E O Annalen Der Physik 532 (3) (2020)
  17. Almpanis E, Amanollahi M, Zamani M Optical Materials 99 109539 (2020)
  18. Zhang Zh M Nano/Microscale Heat Transfer Mechanical Engineering Series Chapter 9 (2020) p. 497
  19. Sloan Ja, Rivera N et al Phys. Rev. B 100 (23) (2019)
  20. Zavislyak I, Chumak H RADIOFIZ. ELEKTRON. 24 (1) 3 (2019)
  21. Fesenko V I, Tuz V R Phys. Rev. B 99 (9) (2019)
  22. Zavislyak I, Chumak H Radioelectron.Commun.Syst. 62 (8) 377 (2019)
  23. Zavislyak I V, Chumak G L Izvestiya Vuzov. Radioelektronika 62 (8) 455 (2019)
  24. Litinskaya M Reference Module in Materials Science and Materials Engineering (2019)
  25. Amanollahi M, Moncada-Villa E, Zamani M Journal Of Magnetism And Magnetic Materials 484 234 (2019)
  26. Yarbrough P M, Livesey K L et al Phys. Rev. Applied 12 (2) (2019)
  27. Tuz V R, Fedorin I V, Fesenko V I Surface Waves - New Trends and Developments Chapter 6 (2018)
  28. Tuz V R, Fesenko V I et al Journal of Applied Physics 121 (10) (2017)
  29. Bozhko D A, Clausen P et al Phys. Rev. Lett. 118 (23) (2017)
  30. Zavislyak I V, Chumak H Radioelectron.Commun.Syst. 60 (11) 469 (2017)
  31. Abirami N, Joseph W K S Sensing And Bio-Sensing Research 16 37 (2017)
  32. Tuz V R Journal Of Magnetism And Magnetic Materials 419 559 (2016)
  33. Panyaev I S, Sannikov D G J. Opt. Soc. Am. B 33 (2) 220 (2016)
  34. Subkhangulov R R, Mikhaylovskiy R V et al Nature Photon 10 (2) 111 (2016)
  35. Fesenko V I, Fedorin I V, Tuz V R Opt. Lett. 41 (9) 2093 (2016)
  36. Dzedolik I V Springer Series In Optical Sciences Vol. Contemporary OptoelectronicsPhonon-Polaritons in Nonlinear Dielectric Medium199 Chapter 1 (2016) p. 3
  37. Gazizulin R R, Bunkov Yu M, Safonov V L Jetp Lett. 102 (11) 766 (2015)
  38. Electromagnetic Phenomena in Matter 1 (2015) p. 689
  39. Badrtdinov G S, Mitlina L A, Kosareva E A Russ Phys J 57 (8) 1008 (2014)
  40. Badrtdinov G S, Mitlina L A Russ Phys J 57 (1) 115 (2014)
  41. Mitlina L A, Mitlina L A i dr Vestnik Samarskogo Gosudarstvennogo Tekhnicheskogo Universiteta. Seriya Fiziko-matematicheskie Nauki 2(35) 168 (2014)
  42. Dzedolik I V, Karakchieva O Appl. Opt. 52 (25) 6112 (2013)
  43. Sannikov D G, Sementsov D I Phys. Solid State 55 (11) 2324 (2013)
  44. Tagiyeva R T, Tanatar B J Supercond Nov Magn 25 (8) 2577 (2012)
  45. Nonequilibrium Magnons 1 (2012) p. 179
  46. Chupis I E Low Temperature Physics 38 (2) 175 (2012)
  47. Gunawan V, Stamps R L J. Phys.: Condens. Matter 24 (40) 406003 (2012)
  48. Kraus L, Frait Z et al Journal of Applied Physics 111 (5) (2012)
  49. Tarkhanyan R H PIER B 39 55 (2012)
  50. Gulyaev Yu V, Tarasenko S V, Shavrov V G Uspekhi Fizicheskikh Nauk 181 (6) 595 (2011)
  51. Dzedolik I V, Karakchieva O S 2011 11th International Conference on Laser and Fiber-Optical Networks Modeling (LFNM), (2011) p. 1
  52. Sannikov D G, Sementsov D I J. Commun. Technol. Electron. 55 (4) 439 (2010)
  53. Sannikov D G, Sementsov D I Phys. Solid State 52 (4) 680 (2010)
  54. Sannikov D G, Sementsov D I Tech. Phys. Lett. 35 (12) 1100 (2009)
  55. Sannikov D G, Zhirnov S V, Sementsov D I Phys. Solid State 51 (9) 1935 (2009)
  56. Averkov Yu O, Yakovenko V M Tech. Phys. 54 (5) 690 (2009)
  57. Eliseeva S V, Sementsov D I, Stepanov M M Tech. Phys. 53 (10) 1319 (2008)
  58. Khankina S I, Yakovenko V M, Yakovenko I V Tech. Phys. 53 (4) 514 (2008)
  59. Zhirnov S V, Sementsov D I Phys. Solid State 49 (5) 812 (2007)
  60. Averkov Yu O, Yakovenko V M Radiophys Quantum Electron 50 (5) 370 (2007)
  61. Sementsov D I, Shutyi A M Uspekhi Fizicheskikh Nauk 177 (8) 831 (2007)
  62. Heindl R, Srikanth H et al Journal of Applied Physics 101 (9) (2007)
  63. Furs A N, Barkovsky L M J. Phys. A: Math. Theor. 40 (2) 309 (2007)
  64. Gorkunov M V, Lapine M V, Tretyakov S A Crystallogr. Rep. 51 (6) 1048 (2006)
  65. Demokritov S O, Demidov V E et al Nature 443 (7110) 430 (2006)
  66. Averkov Yu O, Yakovenko V M Phys. Rev. B 72 (20) (2005)
  67. JOSEPH WILSON K S, NAVANEETHAKRISHNAN K Mod. Phys. Lett. B 19 (09n10) 425 (2005)
  68. Gracheva N A, Sementsov D I Opt. Spectrosc. 97 (4) 617 (2004)
  69. Tagiyeva R T Phys. Scr. 70 (2-3) 202 (2004)
  70. Albuquerque E L, Cottam M G Polaritons in Periodic and Quasiperiodic Structures (2004) p. 41
  71. Tagiyeva R T Pramana - J Phys 63 (3) 633 (2004)
  72. Tagiyeva R T Superlattices And Microstructures 35 (1-2) 9 (2004)
  73. Tarasenko S V Opt. Spectrosc. 94 (6) 934 (2003)
  74. Marakassov D A, Fisanov V V Russian Physics Journal 45 (10) 976 (2002)
  75. Tagiyeva R T, Saglam M Solid State Communications 122 (7-8) 413 (2002)
  76. Chupis I E, Mishchenko A A Low Temperature Physics 27 (6) 480 (2001)
  77. Vol. Fourth International Kharkov Symposium ’Physics and Engineering of Millimeter and Sub-Millimeter Waves’. Symposium Proceedings (Cat. No.01EX429)Specific features of surface electromagnetic wave propagation in a ferromagnetic semiconductor in the millimeter-wave bandV.L.FalkoS.I.KhankinaV.M.Yakovenko1 (2001) p. 314
  78. Tarasenko S V Opt. Spectrosc. 91 (6) 921 (2001)
  79. Fal’ko V L, Khankina S I, Yakovenko V M Semiconductors 34 (6) 680 (2000)
  80. Mamalui D A, Chupis I E J. Exp. Theor. Phys. 90 (1) 153 (2000)
  81. Chupis I E, Mamaluy D A J. Phys.: Condens. Matter 12 (7) 1413 (2000)
  82. Peisakhovich Yu G, Shtygashev A A J. Exp. Theor. Phys. 91 (1) 188 (2000)
  83. Fal’ko V L, Khankina S I, Yakovenko V M Radiophys Quantum Electron 43 (1) 34 (2000)
  84. Fisanov V V, Marakassov D A Russian Physics Journal 43 (8) 675 (2000)
  85. Tarasenko S V Phys. Solid State 41 (6) 950 (1999)
  86. Vol. MMET Conference Proceedings. 1998 International Conference on Mathematical Methods in Electromagnetic Theory. MMET 98 (Cat. No.98EX114)Eigenwaves of bigyrotropic chiral medium under transverse propagationD.A.MarakasovV.V.Fisanov2 (1998) p. 682
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