神经形态工程学
材料科学
圆极化
异质结
光电子学
晶体管
超短脉冲
光子学
激子
卷积神经网络
全息术
数字微镜装置
纳米技术
光通信
液晶
仿生学
平面的
计算机科学
微电子
极化(电化学)
光学计算
纳米线
纳米光子学
光子晶体
宽带
有机半导体
作者
Yu Zhang,Lingjie Sun,Meiqiu Dong,Ziwei Yu,Kesheng Guo,Yangwu Guo,Cheng Xu,Mingsheng Luo,Yang Deng,Fangxu Yang,Wenping Hu
标识
DOI:10.1002/adma.202517370
摘要
Abstract Emulating the biological visual system's ability to perceive and preprocess circularly polarized light (CPL) offers transformative opportunities for advanced imaging, quantum communication, and autonomous navigation. However, the implementation of such functionality in artificial systems demands the seamless integration of chiral selective sensing, efficient exciton dissociation, and neuromorphic processing capabilities, a combination that remains beyond the reach of current optoelectronic materials. Herein, a mixed‐dimensional heterojunction architecture is presented, integrating a 3D chiral covalent organic framework (COF) with a 2D molecular crystal (2DMC), to overcome these limitations. By constructing a type‐II band‐aligned interface between a β‐ketoenamine‐linked TpPa‐COF and an air‐stable dithienothiophene‐based 2DMC, the architecture enables directional, ultrafast interlayer charge transfer and efficient exciton dissociation at the interface. The resulting chiroptical synaptic transistor achieves a record polarization discrimination ratio ( g EPSC = 0.73) and exceptional photoresponsivity (7.7 × 10 3 A W −1 ), substantially surpassing existing organic CPL‐sensitive detectors. Furthermore, when configured into a 3 × 3 convolutional kernel array, the device enables in‐sensor noise reduction and feature extraction, elevating the classification accuracy of noisy images from 51.5% to 71.2% in the CIFAR‐10 dataset. This work establishes an integrated material platform for CPL‐driven neuromorphic vision, bridging chiral photonics with bioinspired computing.
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