半导体
超短脉冲
红外线的
材料科学
光电导性
探测器
光电子学
红外探测器
噪音(视频)
夜视
偏压
光学
电压
物理
激光器
计算机科学
量子力学
人工智能
图像(数学)
作者
Shiteng Wu,Liyun Qin,Qinliang Li,Ziyu Wu,Zhongquan Nie,Yiqi Jiang,Jianyu Wang,Zhendong Wang,Yangbo Zhou,Kuai Yu,Li Wang,Qisheng Wang
摘要
Traditional infrared semiconductors with direct narrow bandgaps, such as HgCdTe, InGaAs, and lead salts (PbS, PbSe, and PbTe), have been commercialized for decades in various infrared technologies, such as night vision, military communication, and health monitoring. However, traditional infrared (specifically middle- and long-wave infrared) semiconductors suffer from serious noise generation via thermal excitation and external current bias. Although thermal infrared detectors can operate at room temperature, their response speed is very slow, typically on the order of milliseconds or worse, which limits their applications. Herein, we reinvent a classical lead salt semiconductor (PbS) as a room temperature, high speed, and high-detectivity infrared detector. The detection is operated via the self-driven (no bias voltage necessary) photothermoelectric (PTE) effect with a response time reaching 500 ns (limited by the measurement setup)—three orders of magnitude faster than commercial PTE and photoconductive PbS detectors. Furthermore, the physical principle of hot-carrier-dominated heat energy conversion is proposed to understand the unconventional ultrafast response behavior. Combined with high sensitivity at room temperature (noise equivalent power 0.3 pW Hz−1/2) and broadband detection range (0.4–2.3 μm), this hot carrier makes the traditional commercial semiconductor PbS applicable to a class of infrared detection applications.
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