神经形态工程学
计算机科学
宽带
光电二极管
极化(电化学)
响应度
人工智能
人工神经网络
光电子学
可扩展性
光学
光子学
光通信
电子工程
计算机视觉
消色差透镜
物理
可视化
图像传感器
稳健性(进化)
斑点图案
规范化(社会学)
材料科学
通信系统
卷积神经网络
动态范围
机器视觉
斯托克斯参量
作者
Shi Zhang,Shuguang Zhu,Shijian Tian,Libo Zhang,Cheng Chen,Kening Xiao,Wenqi Mo,Shicong Hou,Yunduo Zhang,Yuanfeng Wen,Yiran Tan,Kaixuan Zhang,Jiayue Han,Changlong Liu,Jiale He,Weiwei Tang,Jun Wang,Guanhai Li,Kai Zhang,Lin Wang
标识
DOI:10.1038/s41377-025-02125-0
摘要
Abstract Polarization-sensitive neuromorphic vision sensing excels in distinguishing light polarization states, offering intrinsic advantages in reducing glare and enhancing visual clarity in complex lighting environments, enabling advanced applications in autonomous driving, optical communication, and bioinspired imaging across the visible-to-infrared spectrum. Here, we present a polarization-sensitive neuromorphic phototransistor based on a high-quality, intrinsically anisotropic two-dimensional black arsenic-phosphorus nanosheet, which exhibits exceptional optoelectronic performance with a peak responsivity of 2.88 A W -1 , a polarization ratio of 4.7 and a dynamic range of 40 dB within the near-infrared communication band. Through multidimensional input control, including polarization and gate voltage, the phototransistor successfully simulates synaptic behaviors analogous to human neural responses to visual stimuli, with paired-pulse facilitation values reaching 201%. Critically, the device demonstrates gate-tunable short-term plasticity, with optical persistence triggering stable long-term plasticity states that underpin memory consolidation. The neuromorphic properties enable the development of a hybrid optical-electronic neural network which achieves a classification accuracy of over 90% on the Fashion-MNIST dataset and a reconstruction accuracy of 71.38% using data from the Yale Face Database under 0º linear polarization. We demonstrate a polarization-resolved imaging approach utilizing the black arsenic-phosphorus phototransistor to reconstruct hidden targets with high fidelity through Stokes parameter extraction and degree of linear polarization mapping, revealing intricate polarization features invisible to conventional imaging systems. Our work establishes a foundational platform for high-performance neuromorphic vision systems with integrated polarization imaging, computation, and communication functionalities, addressing critical challenges in scalable brain-inspired optoelectronic technologies.
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