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Electrically and Thermally Tunable Smooth Silicon Metasurfaces for Broadband Terahertz Antireflection
Author(s) -
Ding Lu,
Luo Xianshu,
Cheng Liang,
Thway Maung,
Song Junfeng,
Chua Soo Jin,
Chia Elbert E. M.,
Teng Jinghua
Publication year - 2018
Publication title -
advanced optical materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.89
H-Index - 91
ISSN - 2195-1071
DOI - 10.1002/adom.201800928
Subject(s) - terahertz radiation , materials science , optoelectronics , silicon , metamaterial , broadband , reflection (computer programming) , terahertz time domain spectroscopy , photonics , semiconductor , optics , terahertz spectroscopy and technology , physics , computer science , programming language
Abstract Researches in metamaterials and metasurfaces have significant impact on development of terahertz optics and progression of terahertz science and technologies. Further advancement of terahertz systems demands efficient and versatile tunable and reconfigurable metadevices for manipulating various properties of terahertz radiation. Here an electrically and thermally tunable silicon metasurface for broadband terahertz antireflection application is demonstrated. The silicon metasurface is composed by interdigitated p–n junctions fabricated using a completely complementary metal‐oxide‐semiconductor (CMOS) compatible process in a silicon photonics foundry. It is atomically smooth without any physically etched pattern nor metal antennas. By supplying bias voltage to the p–n junctions, the complex reflection coefficient of the silicon metasurface is continuously tuned between negative and positive values. Complete antireflection condition can be precisely achieved, represented by the vanishing of the echo pulse in terahertz time‐domain spectroscopy (THz‐TDS). The transmission amplitude is bias‐polarity dependent, while the phase is simultaneously manipulated. The active silicon metasurface has a unique property that it thermally tunes the reflection and electrically tunes transmission. The methodology suggests a new design concept using all‐silicon platform for making atomically smooth and electrically controlled metadevices in terahertz and other frequency ranges.