双层
调制(音乐)
基质(化学分析)
光学
几何相位
角动量
光子学
多路复用
自由度(物理和化学)
相位调制
三原子分子
相(物质)
对称(几何)
平面的
物理
领域(数学)
图层(电子)
纳米光子学
纳米柱
工作(物理)
旋涡
光通信
对角化矩阵
S矩阵理论
光隔离器
差分相位
拓扑(电路)
矩阵法
纳米电子学
作者
Chao Feng,Qing Zhong,Tao He,Zeyong Wei,Yuzhi Shi,Zhanshan Wang,Xinbin Cheng
标识
DOI:10.1002/lpor.202501590
摘要
Abstract Full‐channel modulation of the Jones matrix via metasurface has important applications in optical communications, data storage and encryption, but remains a significant challenge. Here, a bilayer triatomic metasurface architecture is proposed for realizing minimalist full‐channel modulation of the Jones matrix. The meta‐atom consists of three high‐transmittance nanopillars, where two nanopillars in the same layer induce intra‐layer light field interference, and the third nanopillar in the adjacent layer breaks the planar symmetry of the meta‐atom. Nine physical degrees of freedom (DoFs), corresponding to the orthogonally polarized propagation phases and geometric phase of each nanopillar, are leveraged to realize full‐channel modulation, which features, to the best of the knowledge, the fewest DoFs and demonstrates superior optical efficiency. Furthermore, four‐channel photonic orbital angular momentum (OAM) multiplexing and eight‐channel image integration based on the proposed methodology are demonstrated. This work exhibits remarkable application potential in ultra‐high‐density information encoding and integration.
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