Nonreciprocal optical propagation by magnetic tamm plasmon polaritons

被引:0
|
作者
Ren, Xiaobin [1 ]
Ren, Kun [2 ]
He, Yumeng [2 ]
机构
[1] Tianjin Univ Sci & Technol, Sch Sci, Tianjin 300222, Peoples R China
[2] Tianjin Univ, Minist Educ, Key Lab Optoelect Informat Technol, Coll Precis Instrument & Optoelect Engn, Tianjin 300072, Peoples R China
来源
2017 INTERNATIONAL CONFERENCE ON OPTICAL INSTRUMENTS AND TECHNOLOGY - MICRO/NANO PHOTONICS: MATERIALS AND DEVICES | 2017年 / 10622卷
关键词
nonreciprocal optical propagation; surface state; transfer matrix method; magneto-optical effect; Tamm plasmon polaritons; graphene photonic crystal;
D O I
10.1117/12.2296527
中图分类号
TB3 [工程材料学];
学科分类号
0805 ; 080502 ;
摘要
We have proposed and realized nonreciprocal light propagation by a structure consisting of graphene photonic crystal and magneto-optical semiconductor. The nonreciprocal transmission is caused by magnetic Tamm plasmon polaritons which exit on the interface of graphene photonic crystal and magneto-optical material. Transmission spectrum is investigated to analyze the influence of structural parameters, external magnetic field, and graphene chemical potential on magnetic Tamm plasmon polaritons. We show that it is possible to realize active control on unidirectional light by altering external magnetic field and graphene chemical potential. And one-way transmission can be easily switched from forward to backward propagation.
引用
收藏
页数:6
相关论文
共 50 条
  • [41] Modified surface plasmon polaritons for the nanoconcentration and long-range propagation of optical energy
    Huawei Liang
    Shuangchen Ruan
    Min Zhang
    Hong Su
    Irene Ling Li
    Scientific Reports, 4
  • [42] Influence of a gold nano-bumps surface lattice array on the propagation length of strongly coupled Tamm and surface plasmon polaritons
    Anulyte, Justina
    Buzavaite-Verteliene, Ernesta
    Vertelis, Vilius
    Stankevicius, Evaldas
    Vilkevicius, Kernius
    Balevicius, Zigmas
    JOURNAL OF MATERIALS CHEMISTRY C, 2022, 10 (36) : 13234 - 13241
  • [43] Room temperature Tamm-Plasmon Exciton-Polaritons in atomic monolayer
    Lundt, N.
    Klembt, S.
    Cherotchenko, E.
    Stoll, S.
    Iff, O.
    Nalitov, A. V.
    Klaas, M.
    Kavokin, A. V.
    Hoefling, S.
    Schneider, C.
    2017 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO), 2017,
  • [44] Tamm plasmon-polaritons and Fabry-Perot excitation in a magnetophotonic structure
    Mikhailova, Tatiana
    Tomilin, Sergey
    Lyashko, Sergey
    Kozhaev, Mikhail
    Shaposhnikov, Alexander
    Karavainikov, Andrey
    Berzhansky, Vladimir
    Belotelov, Vladimir
    OPTICAL MATERIALS EXPRESS, 2022, 12 (02) : 685 - 696
  • [45] Transparent conductive oxides for the epsilon-near-zero Tamm plasmon polaritons
    Bikbaev, Rashid G.
    Vetrov, Stepan Ya
    Timofeev, Ivan, V
    JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS, 2019, 36 (10) : 2817 - 2823
  • [46] Taming parasitic thermal emission by Tamm plasmon polaritons for the mid-infrared
    Puehringer, Gerald
    Jakoby, Bernhard
    JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS, 2018, 35 (07) : 1490 - 1503
  • [47] Second-harmonic generation enhancement in the presence of Tamm plasmon-polaritons
    Afinogenov, B. I.
    Bessonov, V. O.
    Fedyanin, A. A.
    OPTICS LETTERS, 2014, 39 (24) : 6895 - 6898
  • [48] Terahertz refractive index sensor based on Tamm plasmon-polaritons with graphene
    Keshavarz, M. Mehdi
    Alighanbari, Abbas
    APPLIED OPTICS, 2019, 58 (13) : 3604 - 3612
  • [49] Tunable Tamm plasmon polaritons and perfect absorption in a metal-PC cavity
    Li, Liang
    Zhao, Hua
    Zhang, Jingwen
    Hao, Haoyue
    Xing, Fei
    JOURNAL OF PHYSICS D-APPLIED PHYSICS, 2019, 52 (25)
  • [50] Tamm plasmon-polaritons structures with Bi-substituted garnet layers
    Mikhailova, Tatyana
    Shaposhnikov, Alexander
    Prokopov, Anatoly
    Karavainikov, Andrey
    Tomilin, Sergey
    Lyashko, Sergey
    Berzhansky, Vladimir
    MOSCOW INTERNATIONAL SYMPOSIUM ON MAGNETISM (MISM 2017), 2018, 185
12345