光电探测器
材料科学
响应度
光电子学
宽带
光电流
制作
硫系化合物
吸收(声学)
光电效应
暗电流
探测器
比探测率
薄膜
波长
等离子体子
光通信
短波
可见光谱
异质结
硫化铅
过程(计算)
可扩展性
光电导性
作者
Yun Zhao,Lulu Dai,Yuan Ji,Yongkang Wu,Rui Yue,Furong Song,Xuqiang Zhang,Kangkai Hu,Jianbiao Chen,Jian Wang,Jiangtao Chen,Yan Li,Wensheng Li
标识
DOI:10.1002/adom.202503441
摘要
ABSTRACT Cu 2 CdSnSe 4 (CCTSe), a quaternary chalcogenide semiconductor, combines earth‐abundant elements, a high absorption coefficient, and a narrow bandgap, making it an attractive absorber for broadband photodetectors. However, current research on CCTSe photodetectors predominantly relies on vacuum‐based techniques; these methods not only suffer from high costs and complex operation but also face challenges in large‐scale production. To address these limitations, we propose and demonstrate a sulfur‐free precursor one‐step solution process for the fabrication of self‐powered CCTSe thin film photodetectors. By optimizing the selenization process, the resulting CCTSe films exhibit significantly enhanced crystallinity, with effectively suppressed defect states‐key improvements that enable exceptional zero‐bias performance. Specifically, the photodetector achieves a responsivity of 0.52 A/W, a specific detectivity of 5.18 × 10 12 Jones, and a dark current on the order of 10 −9 A. Notably, the device maintains a stable photoresponse under repeated on‐off switching cycles at a typical broadband near‐infrared wavelength 1550 nm, which confirms its excellent photostability and reliable detection capability. These findings validate that the proposed sulfur‐free precursor solution process not only enables high‐performance CCTSe photodetectors but also provides a cost‐effective and scalable pathway for the development of next‐generation broadband visible to near‐infrared optoelectronic devices.
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