偏振器
超材料
太赫兹辐射
材料科学
光电子学
圆极化
极化(电化学)
光学
光谱学
光子学
旋光法
光子超材料
分裂环谐振器
石墨烯
纳米技术
物理
双折射
化学
物理化学
量子力学
散射
微带线
作者
Stephen J. Kindness,Nikita W. Almond,Wladislaw Michailow,Binbin Wei,Kaveh Delfanazari,Philipp Braeuninger‐Weimer,Stephan Hofmann,Harvey E. Beere,D. A. Ritchie,Riccardo Degl’Innocenti
标识
DOI:10.1002/adom.202000581
摘要
Abstract Active control of chirality in artificial media such as metamaterials is fundamental in many scientific areas, ranging from research into fundamental optical phenomena to the investigation of novel materials, spectroscopy, and imaging. Precise control of the light polarization states has great importance for light‐matter interaction in chemistry and biology, as media with diverse chiral properties react differently to the incoming polarization of light. In this work an active double layer metamaterial device based on vertically stacked ring resonators is realized by integrating electrostatically tunable graphene as an active element. The device is characterized with a THz time domain spectroscopic system demonstrating an all‐electrical control of circular dichroism and optical activity at ≈2 THz, reporting a tunable ellipticity of 0.55–0.98 and >20° rotation of the plane polarization, respectively, by modifying the conductivity of graphene. Further integration with a narrow frequency quantum cascade laser emitting at ≈1.9 THz, in a crossed polarizer experimental arrangement, realizes an active amplitude modulator, hence highlighting the versatility of this approach. These results represent an important milestone for the investigation of novel concepts in optics and in several applications in the THz range, such as wireless communications and spectroscopy.
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