材料科学
光学
太赫兹辐射
宽带
多光谱图像
光电子学
液晶
梁(结构)
光束转向
光束
太赫兹光谱与技术
Crystal(编程语言)
液晶可调谐滤波器
反射率
可见光谱
纳米光子学
空间光调制器
调制(音乐)
作者
Chenglong Liu,Jierong Cheng,Fan Li,Shengnan Guan,Shiying Han,Fei Fan,Sai Chen,Shengjiang Chang
出处
期刊:ACS Photonics
[American Chemical Society]
日期:2026-04-06
卷期号:13 (9): 2687-2695
标识
DOI:10.1021/acsphotonics.6c00283
摘要
Liquid crystal spatial light modulators (LC-SLMs) serve as core components in signal processing and display. However, their research and application in the terahertz band are constrained by three key limitations: low modulation depth, narrow operating bandwidth, and limited spatial resolution. In this study, we demonstrate an LC-SLM that simultaneously mitigates the aforementioned challenges while alleviating their mutual trade-offs. By leveraging polarization conversion within an anisotropic Fabry–Perot cavity constructed by LC metasurfaces, we validate amplitude modulation in transmission mode with a depth exceeding 75% across the frequency range of 0.2–1 THz, excluding only two discrete frequency points. The fabricated 40 × 40 pixel LC-SLM is successfully implemented as a programmable spatial mask for two key THz applications: multispectral single-pixel imaging and beam scanning. When integrated with terahertz time-domain spectroscopy, this system enables the high-fidelity reconstruction of both spatial and spectral information without mechanical movement. Our results open new avenues for advancing compact, low-cost, and efficient components to drive progress in THz imaging and communication systems.
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