On giant amplification of effects of phonon nonspecular reflection at a solitary interface between magnetic and non-magnetic media

Cover Page

Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription Access

Abstract

On the secluded interface of semi-infinite magnetic and non-magnetic media, hybridiza-tion of magnetoelastic interaction with inhomogeneous exchange or magneto-dipole interaction can lead to the formation of symmetry-protected bound states in the radiation spectrum of the leaky surface magnon polarons. If a quasi-plane bulk elastic wave falls on the surface of a magnetic medium from outside, and the wave parameters approach to the parameters of the surface “dark” state of the above mentioned type, the nonspecular reflection effects of the first order increase unrestrictedly (in the non-dissipative approximation).

Full Text

Restricted Access

About the authors

Yu. V. Gulyaev

Institute of Radio Engineering and Electronics named after Kotelnikov, Russian Academy of Sciences

Email: shavrov@cplire.ru

Academician of the RAS

Russian Federation, Moscow

O. S. Sukhorukova

Donetsk State University; Donetsk Institute for Physics and Engineering named after Galkin

Email: shavrov@cplire.ru
Russian Federation, Donetsk; Donetsk

A. S. Tarasenko

Donetsk Institute for Physics and Engineering named after Galkin

Email: shavrov@cplire.ru
Russian Federation, Donetsk

S. V. Tarasenko

Donetsk Institute for Physics and Engineering named after Galkin

Email: shavrov@cplire.ru
Russian Federation, Donetsk

V. G. Shavrov

Institute of Radio Engineering and Electronics named after Kotelnikov, Russian Academy of Sciences

Author for correspondence.
Email: shavrov@cplire.ru
Russian Federation, Moscow

References

  1. Maekawa S., Kikkawa T., Chudo H., Ieda J., Saitoh E. Spin and spin current – From fundamentals to recent progress Journal of Applied Physics. 2023. V. 133(2). P. 020902.
  2. Пекар С.И. Исследования по электронной теории кристаллов. М.–Л.: ГТТЛ, 1951. 256 с.
  3. Гуляев Ю.В., Сухорукова О.С., Тарасенко А.С., Тарасенко С.В., Шавров В.Г. “Суперрезонансные” состояния в спектре вытекающих поверхностных магнонных поляронов. // ДАН. 2022. Т. 505. № 1. С. 10–15.
  4. Azzam S.I., Kildishev A.V. Photonic Bound States in the Continuum: from Basics to Applications // Adv. Opt. Mater. 2021. V. 9. P. 2001469.
  5. Бреховских Л.М. Волны в слоистых средах. М.: Изд-во АН СССР, 1957. 502 c.
  6. Favretto-Cristini N., Komatitsch D., Carcione J.M., Cavallini F. Elastic surface waves in crystals. Pt 1: Review of the physics // Ultrasonics. 2011. V. 51(6). P. 653–660.
  7. Гуляев Ю.В., Тарасенко С.В., Шавров В.Г. Электромагнитный аналог вытекающей поверхностной упругой волны первого типа для уединенной границы раздела прозрачных диэлектриков // УФН. 2020. Т. 190. № 9. С. 933–949.
  8. Ожогин В.И., Преображенский В.Л. Ангармонизм смешанных мод и гигантская акустическая нелинейность антиферромагнетиков // УФН. 1988. Т. 155. № 4. С. 593–621.
  9. Такер Дж., Рэмптон В. Гиперзвук в физике твердого тела. М.: Мир, 1975. 453 c.
  10. Гуляев Ю.В., Тарасенко С.В., Шавров В.Г. Спин-волновая акустика антиферромагнитных структур как магнитоакустических метаматериалов // УФН. 2011. Т. 181. № 6. С. 595–626.
  11. Балакирев М.К., Гилинский И.А. Волны в пьезокристаллах. Новосибирск: Наука, 1982. 240 с.
  12. Bertoni H.L., Tamir T. Unified theory of Rayleigh-angle phenomena for acoustic beams at liquid-solid interfaces // Appl. Phys. 1973. V. 2. P. 157–172.
  13. Бреховских Л.М., Годин О.А. Акустика слоистых сред. М.: Наука, 1989. 414 с.
  14. Auld B.A. Acoustic Fields and Waves in Solids. N.Y.: J. Willey, 1973. 423 p.
  15. Chauvat D., Emile O., Bretenaker F., A. Le Floch Direct Measurement of the Wigner Delay Associated with the Goos–Hänchen Effect Phys. Rev. Lett. // 2000. V. 84. P. 71–74.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download
2. Fig. 1. Dependence of the maximum value of the Schoch displacement ∆S ≡ ∆(h = hN(ω), ϑ) on the degree of proximity of the angle of incidence of a quasi-plane wave to the point of formation of a surface symmetrically protected SSC (3), (19), (20) (ϑ = 0).

Download (42KB)
Indexing metadata

Copyright (c) 2024 Russian Academy of Sciences

This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies