太赫兹辐射
材料科学
可重构性
无线
计算机科学
可扩展性
天线(收音机)
光电子学
频道(广播)
对象(语法)
电子工程
调制(音乐)
透视图(图形)
光束转向
相(物质)
功率(物理)
光通信
相变
光子学
智能天线
光伏系统
千兆位
带宽(计算)
可重构天线
通信系统
模块化(生物学)
真延时
通信卫星
互联网
光学
作者
Yat Sing To,Jiachen Du,Cyril Decroze,Laure Huitema,Aurélian Crunteanu,Hang Wong
标识
DOI:10.1002/adfm.202515085
摘要
Abstract Terahertz (THz) wireless technology offers unprecedented capabilities in sensing, imaging, and communication for 6G perceptive networks. Recent reconfigurable THz metasurfaces enable adaptive beam manipulation, supporting diverse functionalities like frequency, polarization, spatial, and temporal adjustments for rapid communications and object tracking. However, these are hindered by multilayer complexity, insertion losses, and scalability challenges. Here, it is overcome these constraints by realizing a pioneering single‐layer, optically activated tunable metasurface incorporating Germanium Telluride ( GeTe ) material, acquiring multifunctional THz sensing, imaging, and communication within a unified platform for the first time. GeTe ’s low‐power, non‐volatile switching facilitates dynamic reconfiguration, eliminating bulky bias networks of traditional THz metasurfaces. This measured metasurface delivers an adaptive sub‐THz communication channel with extensive coverage and enhanced passive object detection via wide frequency‐dispersive scanning. Leveraging phase‐change material‐driven tunability, this antenna technique enables efficient, adaptive 6G connectivity and high‐precision localization, with transformative potential for low Earth orbit networks, smart cities, and advanced Internet of Things (IoT).
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