1. Blackbody-sensitive room-temperature infrared photodetectors based on low-dimensional tellurium grown by chemical vapor deposition
- Author
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Lili Zhang, Fang Zhong, Yan Ye, Zhigao Hu, Wei Jiang, Xiaohao Zhou, Jiangnan Dai, Runzhang Xie, Xiaoshuang Chen, Feng Wu, Hugen Yan, Changqing Chen, Jiafu Ye, Peisong Wu, Yang Wang, Haonan Ge, Zhen Wang, Xun Ge, Meng Peng, Qing Li, Wei Lu, Yuchen Lei, Chongxin Shan, Peng Wang, Weida Hu, Fang Wang, Jianlu Wang, and Jinshui Miao
- Subjects
Electron mobility ,Materials science ,Infrared ,Materials Science ,chemistry.chemical_element ,Photodetector ,02 engineering and technology ,Chemical vapor deposition ,010402 general chemistry ,01 natural sciences ,law.invention ,Responsivity ,law ,Research Articles ,Multidisciplinary ,business.industry ,SciAdv r-articles ,021001 nanoscience & nanotechnology ,Laser ,0104 chemical sciences ,Semiconductor ,chemistry ,Physical Sciences ,Optoelectronics ,0210 nano-technology ,business ,Tellurium ,Research Article - Abstract
Low-dimensional Te-based photodetectors exhibit blackbody response and achieve record-set performance metrics., Blackbody-sensitive room-temperature infrared detection is a notable development direction for future low-dimensional infrared photodetectors. However, because of the limitations of responsivity and spectral response range for low-dimensional narrow bandgap semiconductors, few low-dimensional infrared photodetectors exhibit blackbody sensitivity. Here, highly crystalline tellurium (Te) nanowires and two-dimensional nanosheets were synthesized by using chemical vapor deposition. The low-dimensional Te shows high hole mobility and broadband detection. The blackbody-sensitive infrared detection of Te devices was demonstrated. A high responsivity of 6650 A W−1 (at 1550-nm laser) and the blackbody responsivity of 5.19 A W−1 were achieved. High-resolution imaging based on Te photodetectors was successfully obtained. All the results suggest that the chemical vapor deposition–grown low-dimensional Te is one of the competitive candidates for sensitive focal-plane-array infrared photodetectors at room temperature.
- Published
- 2021
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