High‐Speed Short Infrared Detector Based on Vertical Gr/Se0.2Te0.8/GaAs Heterojunction

High‐Speed Short Infrared Detector Based on Vertical Gr/Se0.2Te0.8/GaAs Heterojunction

In the domain of high‐performance short‐wave infrared (SWIR) photodetection and imaging, existing technologies predominantly utilize single‐crystal germanium and III‐V semiconductors. Despite their efficacy, these materials are encumbered by laborious synthesis and complex fabrication demands. In th...

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Veröffentlicht in:Laser & photonics reviews 2024-12, Vol.18 (12), p.n/a
Hauptverfasser: Yang, Chong, Yu, He, Lian, Yunlu, Liu, Yiming, Wu, Maoyi, Yang, Xiutao, Han, Jiayue, Dong, Xiang, Gou, Jun, Zheng, Xing, Wu, Zhiming, Jiang, Yadong, Wang, Jun
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Sprache:eng
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Carrier mobility
Gallium arsenide
Germanium
Graphene
Heterojunctions
Heterostructures
high speed
Infrared detectors
Infrared imaging
photodetectors
Photometers
Se0.2Te0.8
Semiconductors
short‐wave infrared
Synthesis
Thin films
Vacuum thermal evaporation
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container_issue 12
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container_title Laser & photonics reviews
container_volume 18
creator Yang, Chong
Yu, He
Lian, Yunlu
Liu, Yiming
Wu, Maoyi
Yang, Xiutao
Han, Jiayue
Dong, Xiang
Gou, Jun
Zheng, Xing
Wu, Zhiming
Jiang, Yadong
Wang, Jun
description In the domain of high‐performance short‐wave infrared (SWIR) photodetection and imaging, existing technologies predominantly utilize single‐crystal germanium and III‐V semiconductors. Despite their efficacy, these materials are encumbered by laborious synthesis and complex fabrication demands. In this study, the synthesis of large‐area, high‐crystallinity Se0.2Te0.8 thin films through a CMOS‐compatible vacuum thermal evaporation process is reported. A high‐speed, broad‐spectrum photodetector engineered with an innovative Gr/Se0.2Te0.8/GaAs vertical heterostructure is presented, which capitalizes on the augmented carrier mobility and employs graphene innovatively as both a carrier collection interface and an electrode. This configuration facilitates a remarkably swift response time of 800 ns/1 µs at the crucial 1310 nm wavelength for optical communications. Moreover, the fabrication of a 5 × 5 array device demonstrates substantial SWIR imaging capabilities at ambient conditions, marking a paradigm shift in uncooled infrared imaging and communication technologies. This work not only extends the boundaries of SWIR photodetector performance but also underscores the potential of novel material systems in high‐speed optical applications. The high‐crystallinity Se0.2Te0.8 thin film with high carrier mobility is synthesized via thermal evaporation. Furthermore, a high‐speed broadband photodetector based on the Gr/Se0.2Te0.8/GaAs vertical heterostructure is developed, achieving remarkably swift response times in the nanosecond range at 1310 nm and under 10 µs at 1550 nm. This outstanding performance highlights its significant potential in the field of optical communications.
doi_str_mv 10.1002/lpor.202400561
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subjects Carrier mobility
Gallium arsenide
Germanium
Graphene
Heterojunctions
Heterostructures
high speed
Infrared detectors
Infrared imaging
photodetectors
Photometers
Se0.2Te0.8
Semiconductors
short‐wave infrared
Synthesis
Thin films
Vacuum thermal evaporation
title High‐Speed Short Infrared Detector Based on Vertical Gr/Se0.2Te0.8/GaAs Heterojunction
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