A multi-dimensional photodetector based on an α-MoO 3 grating and graphene

Integration of multi-dimensional optical information enhances the recognition and anti-interference capabilities of the detection system, allowing for better adaptation to complex environments. Therefore, this technology represents a crucial developmental pathway for the future of infrared optical d...

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Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2024-06, Vol.26 (24), p.17102-17109
Main Authors: Wang, Yating, Wang, Mingjun, Liu, Haotuo, Wu, Biyuan, Wang, Xinyue, Wu, Xiaohu
Format: Article
Language:English
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Summary:Integration of multi-dimensional optical information enhances the recognition and anti-interference capabilities of the detection system, allowing for better adaptation to complex environments. Therefore, this technology represents a crucial developmental pathway for the future of infrared optical detectors. In this study, a dual-band polarization photodetector based on a two-dimensional α-MoO grating structure is proposed. The structure utilizes the special dispersion property of the α-MoO material to excite the localized plasmon resonance, which generates narrowband high absorption peaks with -factors as high as 110.24 and 92.65, with peaks close to 1 under TM and TE polarized waves, respectively. The direct measurement of multi-dimensional optical information including intensity, spectrum and polarization states is realized. By adjusting the structural parameters, polarization-dependent dual-band detection can be achieved. Meanwhile, the introduction of graphene material realizes the electronically tunable function of the device. This study provides unexplored strategies for realizing more efficient, flexible and versatile dual-band polarization wave detection.
ISSN:1463-9076
1463-9084
DOI:10.1039/d4cp01293c