纳米光子学
石墨烯
极化子
拓扑(电路)
异质结
各向异性
材料科学
光子学
超材料
纳米技术
光电子学
物理
工作(物理)
超晶格
纳米电子学
作者
Hanchao Teng,Chengyu Jiang,Min Liu,Yunpeng Qu,Zhou Sh,Zhuoxin Xue,H. Y. Zhu,Jiayi Gui,Shuang Xi,Yejing Yang,Na Chen,Hai Hu,Qing Dai
出处
期刊:Nano Letters
[American Chemical Society]
日期:2026-01-26
卷期号:26 (8): 2923-2931
被引量:2
标识
DOI:10.1021/acs.nanolett.5c06162
摘要
Achieving active, multistate control over the topology of in-plane polaritons is crucial for developing advanced nanophotonic devices, yet existing platforms are fundamentally limited by intrinsic structures of natural materials or restricted tuning mechanisms. Here, we overcome these limitations by introducing a graphene grating/α-MoO3 heterostructure that merges static, synthetic geometric design with dynamic tuning via doping. By engineering the interaction between the intrinsic anisotropy of α-MoO3 and the tunable synthetic anisotropy of the graphene metasurface, we realize a doping-driven re-entrant topological transition (Hyperbolic-Elliptic-Hyperbolic). Moreover, we show that the system can be designed to exhibit a predetermined number of topological transitions by geometrically setting the fill factor of the grating. Finally, by rotationally misaligning the two anisotropic axes, we experimentally validate tilted, asymmetric polaritons and vortex-like patterns via s-SNOM. This work establishes a framework for programming polaritonic topology, directionality, and symmetry, opening a route toward advanced reconfigurable nanophotonic devices.
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