Jinjie Lu , Qiyuan Zhang , Niangjuan Yao , Siyuan Lei , Yingjian Ren , Chengyu Leng , Yanqing Gao , Wei Zhou , Lin Jiang , Zhiming Huang , Junhao Chu
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引用次数: 0
摘要
太赫兹(THz)波作为电磁波谱中微波与红外光之间的过渡区域,在高速通信、生物医学成像、天文光谱分析、无损安全检测等领域显示出独特的技术优势。然而,由于材料带隙不匹配、暗电流严重、吸收低等因素,太赫兹探测面临着关键的技术瓶颈。本研究采用化学气相传输(CVT)法制备了高质量的SnSb2Te4单晶,并在室温下制备了可见光到太赫兹波的广谱光探测器,其特征频率分别为0.0249 THz、0.346 THz和0.509 THz,高响应率分别为16,162、8077和3434 A W-1,超低噪声等效功率为7.33 fW Hz-1/2,快速响应时间为12 μs。研究结果表明,基于snsb2te4的光电探测器在下一代广谱光电器件中具有重要的应用前景。
Wideband photoelectric detector based on SnSb2Te4 single crystal at room temperature
Terahertz (THz) wave, as the transition region between microwave and infrared light in the electromagnetic spectrum, shows unique technical advantages in the fields such as high-speed communication, biomedical imaging, astronomical spectral analysis, and non-destructive security inspection. However, THz detection faces key technological bottlenecks due to the factors of unmatched material bandgap, serious dark current, and low absorption. In this study, high quality of SnSb2Te4 single crystal was prepared by chemical vapor transport (CVT) and wide-spectrum photo detectors were fabricated from visible light to THz wave at room temperature with high responsivities of 16,162, 8077, and 3434 A W-1 at characteristic frequencies of 0.0249 THz, 0.346 THz, and 0.509 THz, respectively, as well as ultra-low noise equivalent power of 7.33 fW Hz-1/2 and fast response time of 12 μs. Our results demonstrate that SnSb2Te4-based photoelectric detectors have significant application prospects in the next generation of wide-spectrum optoelectronic devices.
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