Enviar artigo por via de e-mail Electroacoustic Shear Waves in the Hollow Structure of Two Piezoelectric
- Autores: Vilkov E.A.1, Nikitov S.A.2,3,4
-
Afiliações:
- Fryazino branch Kotelnikov Institute of Radio-Engineering and Electronics RAS
- Kotelnikov Institute of Radio-Engineering and Electronics, RAS
- Moscow Institute of Physics and Technology (National Research University)
- Saratov National Research State University named after N.G. Chernyshevskiy
- Edição: Volume 70, Nº 4 (2025)
- Páginas: 332-347
- Seção: ON THE 70th ANNIVERSARY OF S.A. NIKITOV
- URL: https://bakhtiniada.ru/0033-8494/article/view/315559
- DOI: https://doi.org/10.31857/S0033849425040028
- EDN: https://elibrary.ru/fstdkv
- ID: 315559
Citar
Acesso aberto
Acesso está concedido
Somente assinantes
Resumo
The results of papers are presented in which dispersion properties of electroacoustic waves in the gap structure of two different piezoelectrics are considered. In particular, it is shown that in the presence of a difference of shear wave velocities in piezoelectrics there are no purely symmetric and antisymmetric modes, and the coefficients of the boundary localization of the shear wave will be significantly different. It is established that at a certain equal level of loss and gain (PT is a symmetrical structure) of two identical piezoelectrics of symmetry class 6, the symmetric and antisymmetric modes intersect. The intersection point defines an exceptional point of the PT-symmetric structure. Taking into account the unequal level of loss and gain in piezoelectrics results in either intersection, touching, or convergence of two modes at the point of their degeneracy (exceptional point) in the shear wave spectrum. As in the case of a purely PT-symmetric structure, the frequency dependence of the amplitude at an exceptional point of a quasi PT-symmetric structure (with a rather small difference in loss and gain levels) exhibits a very narrow peak, which opens up the possibility of creating hypersensitive sensors based on them.
Palavras-chave
Sobre autores
E. Vilkov
Fryazino branch Kotelnikov Institute of Radio-Engineering and Electronics RAS
Email: e-vilkov@yandex.ru
Vvedensky Sq. 1, Fryazino, Moscow region, 141120 Russian Federation
S. Nikitov
Kotelnikov Institute of Radio-Engineering and Electronics, RAS; Moscow Institute of Physics and Technology (National Research University); Saratov National Research State University named after N.G. ChernyshevskiyMokhovaya Str., 11, build. 7, Moscow, 125009 Russia Federation; Institutskiy per., 9, Dolgoprudny, Moscow region, 141701 Russian Federation; Bol’shaya Kazach’ya Str., 112, Saratov, 410012 Russian Federation
Bibliografia
- Miao H., Li F. // Ultrasonics. 2021. V. 114. Article No. 106355.
- Xua D., Caia F., Chena M. et al. // Ultrasonics. 2019. V. 93. P. 18.
- Peng X., He W., Xin F. et al. // Ultrasonics. 2020. V. 108. Article No. 106205.
- Zeng L., Zhang J., Liu Y. et al. // Ultrasonics. 2019. V. 96. P. 34.
- Балакирев М.К., Гилинский И.А. Волны в пьезокристаллах. Новосибирск: Наука, 1982.
- Пустовойт В.И. // Успехи физ. наук. 1969. Т. 97. № 2. С. 257.
- Avetisyan A.S. Electroacoustic Waves in Piezoelectric Layered Composites. Cham: Springer, 2023.
- Гуляев Ю.В., Плесский В.П. // Акуст. журн. 1977. Т. 23. № 5. С. 716.
- Балакирев М.К., Горчаков А.В. // ФТТ. 1977. Т. 19. № 2. С. 613.
- Пятаков П.А. // Акуст. журн. 2001. Т. 47. № 6. С. 836.
- Двоешерстов М.Ю., Чередник В.И., Петров С.Г., Чириманов А.П. // Акуст. журн. 2004. Т. 50. № 6. С. 776.
- Guliy O., Zaitsev B., Teplykh A. et аl. // Sensors. 2021. V. 21. P. 1822.
- Гулий О.И., Зайцев Б.Д., Ларионова О.С. и др. // Антибиотики и химиотерапия. 2021. V. 66. № 1–2. С. 12.
- Borodina I.A., Zaitsev B.D., Burygin G.L., Guliy O.I. // Sensors and Actuators B: Chemical. 2018. V. 268. P. 217.
- Borodina I.A., Zaitsev B.D., Teplykh A.A. // Ultrasonics. 2018. V. 82. P. 39.
- Inone М., Moritake H., Toda К., Yoshino К. // Japan. J. Appl. Phys. 2000. V. 39. Pt. 1. № 9B. P. 5632.
- Rico A.J., Martin S.J. // Appl. Phys. Lett. 1987. V. 50. № 21. P. 1474.
- Kondoh J., Saito K., Shiokawa S., Suzuki H. // Japan. J. Appl. Phys. 1996. V. 35. Pt. 1. № 5B. P. 3093.
- Aнисимкин В.И., Анисимкин И.В. // РЭ. 2000. Т. 45. № 7. С. 293.
- Aфанасьев М.С., Вилков Е.А., Бышевский-Конопко О.А., Чучева Г.В. // РЭ. 2024. Т. 69. № 4. С. 394.
- Li X.F., Yang J.S. // Sensors and Actuators. 2006. V. 132A. № 2. P. 472.
- Yang J.S. // Mathematics and Mechanics of Solids. 2006. V. 11. № 5. P. 451.
- Bender C.M., Boettcher S. // Phys. Rev. Lett. 1998. V. 80. № 24. P. 5243.
- El-Ganainy R., Makris K.G., Christodoulides D.N., Musslimani Z.H. // Opt. Lett. 2007. V. 32. № 17. P. 2632.
- Зябловский А.А., Виноградов А.П., Пухов А.А. и др. // Успехи физ. наук. 2014. Т. 184. № 11. С. 1177.
- Schindler J., Lin Z., Lee J.M. et al. // J. Phys. A: Math. Theor. 2012. V. 45. P. 444029.
- Deymier P. Acoustic Metamaterials and Phononic Crystals. Berlin: Springer, 2013.
- Galda A., Vinokur V.M. // Phys. Rev. B. 2016. V. 94. № 2. P. 020408.
- Liu H., Sun D., Zhang C. et al. // Science Advanced. 2019. V. 5. № 11. Article No. eaax9144.
- Miri M.-A., Alù A. // Science. 2019. V. 363. № 6422. Article No. aar7709.
- Doronin I.V., Zyablovsky A.A., Andrianov E.S. et al. // Phys. Rev. A. 2019. V. 100. № 2. P. 021801(R).
- Wang X.-g., Guo G.-h., Berakdar L. // Nature Commun. 2020. V. 11. Article No. 5663.
- Guo A., Salamo G.J., Duchesne D. et al. // Phys. Rev. Lett. 2009. V. 103. № 9. P. 093902.
- Yang Y., Jia H., Bi. Y. et al. // Phys. Rev. Appl. 2019. V. 12. № 3. P. 034040.
- Bилков Е.А., Бышевский-Конопко О.А., Темная О.С. и др. // Письма в ЖТФ. 2022. Т. 48. № 24. С. 38.
- Vilkov E.A., Byshevski-Konopko O.A., Kalyabin D.V., Nikitov S.A. // J. Phys. Cond. Matter. 2023. V. 35. № 43. P. 435001.
- Bилков Е.А., Бышевский-Конопко О.А., Калябин Д.В., Никитов С.А. // Акуст. журн. 2024. № 5. С. 663.
- Соснин А.С., Струков Б.А. Введение в сегнетоэлектричество. М.: Высш. шк., 1970.
- Акустические кристаллы: Справочник / Под ред. М. П. Шаскольской. М.: Наука, 1982.
Arquivos suplementares
