Van der Waals two-color infrared photodetector

Peisong Wu; Lei Ye; Lei Tong; Peng Wang; Yang Wang; Hailu Wang; Haonan Ge; Zhen Wang; Yue Gu; Kun Zhang; Yiye Yu; Meng Peng; Fang Wang; Min Huang; Peng Zhou; Weida Hu

doi:10.1038/s41377-021-00694-4

Van der Waals two-color infrared photodetector

Peisong Wu
, Lei Ye
, Lei Tong
, Peng Wang^*
, Yang Wang
, Hailu Wang
, Haonan Ge
, Zhen Wang
, Yue Gu
, Kun Zhang
, Yiye Yu
, Meng Peng
, Fang Wang
, Min Huang
, Peng Zhou^*
, Weida Hu^*

^*此作品的通讯作者

CAS - Shanghai Institute of Technical Physics
University of Chinese Academy of Sciences
Huazhong University of Science and Technology
Fudan University

科研成果: 期刊稿件 › 文章 › 同行评审

154 引用（Scopus）

摘要

With the increasing demand for multispectral information acquisition, infrared multispectral imaging technology that is inexpensive and can be miniaturized and integrated into other devices has received extensive attention. However, the widespread usage of such photodetectors is still limited by the high cost of epitaxial semiconductors and complex cryogenic cooling systems. Here, we demonstrate a noncooled two-color infrared photodetector that can provide temporal-spatial coexisting spectral blackbody detection at both near-infrared and mid-infrared wavelengths. This photodetector consists of vertically stacked back-to-back diode structures. The two-color signals can be effectively separated to achieve ultralow crosstalk of ~0.05% by controlling the built-in electric field depending on the intermediate layer, which acts as an electron-collecting layer and hole-blocking barrier. The impressive performance of the two-color photodetector is verified by the specific detectivity (D*) of 6.4 × 10⁹ cm Hz^1/2 W⁻¹ at 3.5 μm and room temperature, as well as the promising NIR/MWIR two-color infrared imaging and absolute temperature detection.

源语言	英语
文章编号	6
期刊	Light: Science and Applications
卷	11
期	1
DOI	https://doi.org/10.1038/s41377-021-00694-4
出版状态	已出版 - 12月 2022
已对外发布	是

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abstract = "With the increasing demand for multispectral information acquisition, infrared multispectral imaging technology that is inexpensive and can be miniaturized and integrated into other devices has received extensive attention. However, the widespread usage of such photodetectors is still limited by the high cost of epitaxial semiconductors and complex cryogenic cooling systems. Here, we demonstrate a noncooled two-color infrared photodetector that can provide temporal-spatial coexisting spectral blackbody detection at both near-infrared and mid-infrared wavelengths. This photodetector consists of vertically stacked back-to-back diode structures. The two-color signals can be effectively separated to achieve ultralow crosstalk of \textasciitilde{}0.05\% by controlling the built-in electric field depending on the intermediate layer, which acts as an electron-collecting layer and hole-blocking barrier. The impressive performance of the two-color photodetector is verified by the specific detectivity (D*) of 6.4 × 109 cm Hz1/2 W−1 at 3.5 μm and room temperature, as well as the promising NIR/MWIR two-color infrared imaging and absolute temperature detection.",

author = "Peisong Wu and Lei Ye and Lei Tong and Peng Wang and Yang Wang and Hailu Wang and Haonan Ge and Zhen Wang and Yue Gu and Kun Zhang and Yiye Yu and Meng Peng and Fang Wang and Min Huang and Peng Zhou and Weida Hu",

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T1 - Van der Waals two-color infrared photodetector

AU - Wu, Peisong

AU - Ye, Lei

AU - Tong, Lei

AU - Wang, Peng

AU - Wang, Yang

AU - Wang, Hailu

AU - Ge, Haonan

AU - Wang, Zhen

AU - Gu, Yue

AU - Zhang, Kun

AU - Yu, Yiye

AU - Peng, Meng

AU - Wang, Fang

AU - Huang, Min

AU - Zhou, Peng

AU - Hu, Weida

PY - 2022/12

Y1 - 2022/12

N2 - With the increasing demand for multispectral information acquisition, infrared multispectral imaging technology that is inexpensive and can be miniaturized and integrated into other devices has received extensive attention. However, the widespread usage of such photodetectors is still limited by the high cost of epitaxial semiconductors and complex cryogenic cooling systems. Here, we demonstrate a noncooled two-color infrared photodetector that can provide temporal-spatial coexisting spectral blackbody detection at both near-infrared and mid-infrared wavelengths. This photodetector consists of vertically stacked back-to-back diode structures. The two-color signals can be effectively separated to achieve ultralow crosstalk of ~0.05% by controlling the built-in electric field depending on the intermediate layer, which acts as an electron-collecting layer and hole-blocking barrier. The impressive performance of the two-color photodetector is verified by the specific detectivity (D*) of 6.4 × 109 cm Hz1/2 W−1 at 3.5 μm and room temperature, as well as the promising NIR/MWIR two-color infrared imaging and absolute temperature detection.

AB - With the increasing demand for multispectral information acquisition, infrared multispectral imaging technology that is inexpensive and can be miniaturized and integrated into other devices has received extensive attention. However, the widespread usage of such photodetectors is still limited by the high cost of epitaxial semiconductors and complex cryogenic cooling systems. Here, we demonstrate a noncooled two-color infrared photodetector that can provide temporal-spatial coexisting spectral blackbody detection at both near-infrared and mid-infrared wavelengths. This photodetector consists of vertically stacked back-to-back diode structures. The two-color signals can be effectively separated to achieve ultralow crosstalk of ~0.05% by controlling the built-in electric field depending on the intermediate layer, which acts as an electron-collecting layer and hole-blocking barrier. The impressive performance of the two-color photodetector is verified by the specific detectivity (D*) of 6.4 × 109 cm Hz1/2 W−1 at 3.5 μm and room temperature, as well as the promising NIR/MWIR two-color infrared imaging and absolute temperature detection.

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Van der Waals two-color infrared photodetector

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