Frequency Converters for the Terahertz and Infrared Ranges

A. M. Lerer; Лерер А. М.; G. S. Makeev; Макеева Г. С.; V. V. Cherepanov; Черепанов В. В.

doi:10.31857/S0033849423010084

Frequency Converters for the Terahertz and Infrared Ranges

作者: Lerer A.¹, Makeev G.², Cherepanov V.¹
隶属关系:
1. Southern Federal University
2. Penza State University
期: 卷 68, 编号 1 (2023)
页面: 30-36
栏目: ЭЛЕКТРОДИНАМИКА И РАСПРОСТРАНЕНИЕ РАДИОВОЛН
URL: https://journals.rcsi.science/0033-8494/article/view/138034
DOI: https://doi.org/10.31857/S0033849423010084
EDN: https://elibrary.ru/CDKSIC
ID: 138034

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详细
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详细

A method for solving the problem of nonlinear diffraction on two-dimensional periodic gratings of graphene ribbons has been developed. The third-order nonlinear conductivity of graphene under the action of two waves is taken into account, which is determined by the field of the pump wave, for which we use the field on graphene ribbons obtained by solving the linear diffraction problem. Numerical analysis shows the efficiency of nonlinear frequency conversion in the terahertz and infrared ranges when the frequencies of the incident pump and signal waves coincide with the resonant frequencies of the fundamental and higher order modes of surface plasmon polaritons in graphene ribbons.

关键词

nonlinear diffraction, graphene ribbons, surface plasmon polaritons

参考

Nagatsuma T., Horiguchi Sh., Minamikata Y. et al. // Opt. Express. 2013. V. 21. № 20. P. 23736.
HouY., Jiang C. // Current Chinese Physics. 2021. V. 1. № 3. P. 299. https://doi.org/10.2174/221029810166621020416263
Hu X., Zeng M., Wang A., Zhu L. et al. // Opt. Express. 2015 V. 23. № 20. P. 26158.
Deng H., Huang., He Y., Ye F. // Chinese Physics. B. 2021. V. 30. № 4. P. 044213.
Ooi K. J.A., Cheng J.L., Sipe J.E. et al. // APL Photonics. 2016. V. 1. № 4. P. 046101. https://doi.org/10.1063/1.4948417
Cox J.D., Garcia de Abajo F.J. // ACS Photonics. 2015. V. 2. № 3. P. 306.
Cao J., Kong Y., Gao S., Liu C. // Optics Commun. 2018. V. 406. P. 183.
Лepep A.M. // PЭ. 2012. T. 57. № 11. C. 1160. https://doi.org/10.1134/S106422691210004X
Лерер А.М., Иванова И.Н. // РЭ. 2016. Т. 61. № 5. С. 435. https://doi.org/10.1134/S1064226916050089
Лерер А.М., Макеева Г.С., Черепанов В.В. // РЭ. 2021. Т. 66. № 6. С. 543. https://doi.org/10.31857/S0033849421060188
Hanson G.W. // J. Appl. Phys. 2008. V. 103. № 6. P. 064302.
Cheng J.L., Vermeulen N., Sipe J. // Phys. Rev. B. 2015. V. 91. № 23. P. 235320.
Mikhailov S.A. // Phys. Rev. B. 2016. V. 93. № 8. P. 085403.
Лерер А.М., Иванова И.Н., Макеева Г.С., Черепанов В.В. // Оптика и спектроскопия. 2021. Т. 129. № 3. С. 342.
Cox J.D., Garcia de Abajo F.J. // Accounts Chemical Research. 2019. V. 52. № 9. P. 2536.
Lerer A.M., Makeeva G.S., Cherepanov V.V. // Mater. 2020 Int. Conf. Actual Problems of Electron Devices Engineering (APEDE). Saratov. 24–25 Sept. N.Y.: IEEE, 2020. P. 269. https://doi.org/10.1109/APEDE48864.2020.9255492