暗电流
材料科学
光电子学
量子隧道
红外线的
光电二极管
噪音(视频)
量子效率
响应度
散粒噪声
波长
截止频率
光电探测器
光学
电流密度
泄漏(经济)
噪声系数
信号(编程语言)
雪崩光电二极管
电流(流体)
耗尽区
撞击电离
砷化铟
晶体管
半导体
填充系数
作者
Zihao Wang,Liqi Zhu,Songmin Zhou,Xi Wang,Jian Huang,Xun Li,Zhikai Gan,Chun Lin,Baile Chen
出处
期刊:ACS Photonics
[American Chemical Society]
日期:2025-10-24
卷期号:12 (11): 6294-6299
被引量:1
标识
DOI:10.1021/acsphotonics.5c01773
摘要
Long-wavelength infrared (LWIR) avalanche photodiodes (APDs) serve as the better choice for long-range detection and low-temperature object imaging due to the multiplication gain further enhancing the response sensitivity. However, the tunneling issue occurs in narrow-bandgap devices, and the surface leakage current significantly impacts the device available performance. In this work, we propose a novelty multilayer composition gradient LWIR APD device with a cutoff wavelength of 8 μm to address this series of problems. This design demonstrates high avalanche performance and effectively reduces surface leakage current and suppresses the tunnelling current. At 80 K, the unity-gain dark current of the device is of 7.16 × 10–7 A/cm2 and external quantum efficiency attains a peak of 78% (3.93 A/W) at 6.31 μm. This APD also displays a gain of 280 and low excess noise factor of 1.1. At a gain of 280, the device has a gain-normalized dark current density of 0.09 A/cm2. Furthermore, when the temperature increases to 160 K, the dark current remains relatively lower at 8 × 10–2 A/cm2, with a gain of 37 and an excess noise factor of less than 1.28. Thus, the composition gradient layers enable state-of-the-art performance in dark current, gain, and excess noise among LWIR APDs. This makes it highly promising for weak signal detection, imaging, and free-space optical communication applications.
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