波前
太赫兹辐射
材料科学
可重构性
光电子学
光学
硫系化合物
光束转向
可编程逻辑器件
宽带
波前传感器
自适应光学
梁(结构)
可擦除可编程逻辑器件
相(物质)
计算机科学
光子学
波导管
变形镜
相干控制
作者
Guanxuan Guo,Yisheng Dong,Y R Li,Mengshu Liu,Fangzhou Shu,Xieyu Chen,Quan Xu,Xueqian Zhang,Zhen Tian,Jiaguang Han
摘要
ABSTRACT Compact and programmable wavefront control is a central task for advancing terahertz (THz) wave spectroscopy, imaging, and wireless communications. Although electrically programmable metasurfaces have exhibited remarkable versatility and significantly promoted THz dynamic device development, realizing two‐dimensional (2D), nonvolatile, broadband, and high‐resolution wavefront control remains a critical objective. Here, we present an optically programmable metasurface method that potentially overcomes these difficulties by leveraging the reversible phase change of the chalcogenide material Ge 2 Sb 2 Te 5 (GST). The core innovation lies in the use of selective optical excitation to locally address and induce phase changes in constituent GST patches, enabling reconfigurable and nonvolatile reversal of the meta‐atom symmetry. This unique mechanism yields a robust and broadband 0/π phase‐switching capability at the meta‐atom level, operating with subwavelength resolution and without the need for complex integrated electrodes. By employing spatially patterned optical pumping with predesigned masks as examples, we experimentally demonstrate two distinct 2D coded functionalities: controllable beam steering and tunable beam focusing. Our method establishes a new paradigm for programmable THz metasurfaces, offering a promising pathway for active and flexible THz wavefront engineering critical for systems requiring long‐term, stable functionalities.
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