拓扑绝缘体
光子学
纳米材料
量子阱
光电子学
材料科学
量子
物理
纳米技术
光学
量子力学
激光器
作者
Haiteng Wang,Junru Niu,Qiaolu Chen,Sihan Zhao,Shao Hua,Yihao Yang,Hongsheng Chen,Shilong Li,Haoliang Qian
出处
期刊:Nanophotonics
[De Gruyter]
日期:2024-06-26
卷期号:13 (18): 3575-3580
被引量:6
标识
DOI:10.1515/nanoph-2024-0197
摘要
Abstract All-optical modulators hold significant prospects for future information processing technologies for they are able to process optical signals without the electro-optical convertor which limits the achievable modulation bandwidth. However, owing to the hardly-controlled optical backscattering in the commonly-used device geometries and the weak optical nonlinearities of the conventional material systems, constructing an all-optical modulator with a large bandwidth and a deep modulation depth in an integration manner is still challenging. Here, we propose an approach to achieving an on-chip ultrafast all-optical modulator with ultra-high modulation efficiency and a small footprint by using photonic topological insulators (PTIs) made of metallic quantum wells (MQWs). Since PTIs have attracted significant attention because of their unidirectional propagating edge states, which mitigate optical backscattering caused by structural imperfections or defects. Meanwhile, MQWs have shown a large Kerr nonlinearity, facilitating the development of minimally sized nonlinear optical devices including all-optical modulators. The proposed photonic topological modulator shows a remarkable modulation depth of 15 dB with a substantial modulation bandwidth above THz in a tiny footprint of only 4 × 10 µm 2 , which manifests itself as one of the most compact optical modulators compared with the reported ones possessing a bandwidth above 100 GHz. Such a high-performance optical modulator could enable new functionalities in future optical communication and information processing systems.
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