太赫兹辐射
分光计
光电子学
光子学
材料科学
太赫兹光谱与技术
光电探测器
光子
色散(光学)
光谱分辨率
太赫兹间隙
光子计数
等离子体子
光学
探测器
计算机科学
热辐射计
能量(信号处理)
近红外光谱
微尺度化学
数码产品
光谱学
成像光谱仪
小型化
照相混合
物理
深度学习
分辨率(逻辑)
多光谱图像
光谱成像
作者
Shiqiang Zhao,Yongzheng Wen,Chen Wang,Jun Zhang,Maxwell Aaron Wallace,Feilou Wang,Kaixin Yu,Jingbo Sun,Ji Zhou
标识
DOI:10.1002/lpor.202501565
摘要
Abstract Miniaturized terahertz spectrometers hold revolutionary potential for portable real‐time spectral analysis, yet reports on such devices remain scarce. Existing compact spectrometers typically rely on microscale dispersive elements or tunable photodetector arrays, but these approaches face limitations in the terahertz regime due to their low photon energy and long wavelength. Here, a terahertz spectrometer framework is introduced by integrating dispersion and detection functionalities in one metasurface via magneto‐electric coupling processes. Such frameworks are self‐powered and in wavelength‐scale footprint, which apply to both point‐by‐point spectral reconstruction and computational one. Especially, assisted by deep learning techniques, spectral reconstructions with high spectral resolution and speed can be achieved, and over 15 000 spectra can be acquired in <1 min. By offering significance in compactness and acquisition efficiency, this strategy paves the way for miniaturized terahertz spectroscopy, novel functionalities of optoelectronics, and advanced integrated photonic platforms.
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