摘要
Objects with different shapes,materials and temperatures can emit distinct polarizations and spectral information in mid-infrared band,which provides a unique signature in the transparent window for object identification.However,the crosstalk among various polarization and wavelength channels prevents from accurate mid-infrared detections at high signal-to-noise ratio.Here,we report full-polarization metasurfaces to break the inherent eigen-polarization constraint over the wavelengths in mid-infrared.This recipe enables to select arbitrary orthogonal polarization basis at individual wavelength independently,therefore alleviating the crosstalk and efficiency degradation.A six-channel all-silicon metasurface is specifically presented to project focused mid-infrared light to distinct positions at three wavelengths,each with a pair of arbitrarily chosen orthogonal polarizations.An isolation ratio of 117 between neighboring polarization channels is experimentally recorded,exhibiting detection sensitivity one order of magnitude higher than existing infrared detectors.Remarkably,the high aspect ratio~30 of our meta-structures manufactured by deep silicon etching technology at temperature−150℃ guarantees the large and precise phase dispersion control over a broadband from 3 to 4.5μm.We believe our results would benefit the noise-immune mid-infrared detections in remote sensing and space-to-ground communications.
基金
supported by National Key Research and Development Program of China(2018YFA0306200,2017YFA0700200,2017YFA0700202)
National Natural Science Foundation of China(62204249,62222514,61731010,61875218,61991440,and 91850208)
Youth Innovation Promotion Association of Chinese Academy of Sciences(Y2021070)
Strategic Priority Research Program of Chinese Academy of Sciences(XDB43010200)
Shanghai Rising-Star Program(20QA1410400)
Shanghai Science and Technology Committee(23ZR1482000,20JC1416000,and 22JC1402900)
Natural Science Foundation of Zhejiang Province(LR22F050004)
Shanghai Municipal Science and Technology Major Project(2019SHZDZX01)
Shanghai Human Resources and Social Security Bureau(2022670)
China Postdoctoral Science Foundation(2022TQ0353 and 2022M713261)
partially carried out at the Center for Micro and Nanoscale Research and Fabrication in University of Science and Technology of China
the support by AME Individual Research Grant(IRG)funded by A*STAR,Singapore(Grant No.A2083c0060).
