Tunable magneto-optical polarization device for terahertz waves based on InSb plasmonic structure

Conference on Lasers and Electro-optics : (CLEO). Conference on Lasers and Electro-optics Pub Date : 2019-05-05 DOI:10.1364/CLEO_SI.2019.SW3F.1

Qianyi Mu, Fei Fan, Jierong Cheng, Shengjiang Chang

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Abstract

The non-reciprocal circular dichroism and Faraday rotation effect for terahertz (THz) waves in longitudinally magnetized InSb were investigated by the theoretical and experimental studies in the THz regime, which indicated its ability for THz circular polarized isolator, THz circular polarizer, tunable polarization converter, and polarization modulator by the manipulation of the different magnetic fields. Furthermore, we demonstrated the InSb plasmonics based on its magneto-optical effects combined with artificial microstructure. We found the magneto-optical enhancement mechanisms in this magneto plasmonic structure, achieving broadband perfect orthogonal linear polarization conversion modulated by the weak magnetic field in the experiment. Moreover, the magneto-optical modulation with modulation depth of 95% and one-way transmission with the isolation of 33dB can be achieved by this device under a weak magnetic field of 150mT. InSb and its magnetoplasmonic device have broadly potentials for THz isolator, magneto-optical modulator, and polarization convertor in the THz application systems.

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基于InSb等离子体结构的太赫兹可调谐磁光偏振装置

通过对纵向磁化InSb中太赫兹波的非倒易圆二色性和法拉第旋转效应的理论和实验研究，证明了其在不同磁场下可作为太赫兹圆极化隔离器、太赫兹圆极化器、可调谐极化变换器和偏振调制器的能力。此外，我们还展示了基于其磁光效应与人工微观结构相结合的InSb等离子体。我们在该磁等离子体结构中发现了磁光增强机制，在实验中实现了弱磁场调制的宽带完美正交线性极化转换。在150mT弱磁场下，该器件可实现调制深度为95%的磁光调制和隔离度为33dB的单向传输。在太赫兹应用系统中，InSb及其磁等离子体器件在太赫兹隔离器、磁光调制器和极化变换器等方面具有广泛的应用前景。

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Conference on Lasers and Electro-optics : (CLEO). Conference on Lasers and Electro-optics

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