光探测
光电探测器
神经形态工程学
材料科学
光电子学
水下
异质结
响应度
可穿戴计算机
吸收(声学)
半导体
纳米技术
光电二极管
噪音(视频)
载流子
微电子
光电流
光伏系统
计算机科学
石墨烯
突触
光通信
能量(信号处理)
可穿戴技术
响应时间
晶体管
光子学
作者
Qianyi Cheng,Chuyue Qiao,Yu Chen,Shaopeng Fu,Jianxian Zhou,Xiangyu Chen,Zhixun Wang,Jian-feng Li,Lei Wei,Qichong Zhang,Qianyi Cheng,Chuyue Qiao,Yu Chen,Shaopeng Fu,Jianxian Zhou,Xiangyu Chen,Zhixun Wang,Jian-feng Li,Lei Wei,Qichong Zhang
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-11-12
卷期号:19 (46): 40170-40183
标识
DOI:10.1021/acsnano.5c16053
摘要
The development of high-performance blue-light-sensitive photodetectors for underwater applications faces significant challenges due to the limited absorption range and inefficient charge separation in conventional semiconductor materials. Here, we design a TiO2@CdS core-shell heterojunction that synergistically combines the advantages of both materials, significantly enhancing blue-light absorption (450-495 nm) and charge carrier separation efficiency. The resulting fiber-shaped photoelectrochemical photodetector (FPPD) displays exceptional performance with a high responsivity of 101.87 mA W-1, fast response time of <19 ms, and outstanding mechanical flexibility. Furthermore, our FPPD exhibits biomimetic synaptic functionalities including bilingual responses, short-term plasticity, and low energy consumption comparable to that of biological synapses, enabling neuromorphic information perception and computing capabilities. Practical applications in underwater optical communication, imaging, and human-machine interaction are successfully demonstrated, highlighting the FPPD's versatility in underwater environments. This work not only advances the design of high-performance underwater optoelectronic devices but also establishes a direct connection between traditional photodetection and emerging neuromorphic computing, laying the groundwork for innovative underwater systems and wearable technologies.
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