2D-materials-based optoelectronic synapses for neuromorphic applications

IF 42.9 Q1 ELECTROCHEMISTRY eScience Pub Date : 2023-08-30 DOI:10.1016/j.esci.2023.100178
Jiaxin Chen , Wentao Xu
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Abstract

Optoelectronic artificial synapses (OEASs) are essential for realizing artificial neural networks (ANNs) in next-generation information processing that has high transmission speed, high bandwidth, and low power consumption. Two-dimensional (2D) materials endowed with strong light-matter interactions and atomically thin dangling-bond-free surfaces are candidates for achieving versatile optoelectronics. Developing 2D OEASs for future neuromorphic applications is significant to break the bottleneck of von Neumann architecture and achieve future artificial intelligence systems. This review primarily focuses on recent developments in advanced 2D OEASs, discussing their working mechanism as well as potential applications. Common materials, device structures, and their synthesis and construction methods are also summarized. Finally, the prospects for future 2D OEASs from the perspectives of materials, performance, and applications are briefly described.

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用于神经形态学应用的基于2d材料的光电突触
光电人工突触(OEASs)是实现高传输速度、高带宽、低功耗的下一代信息处理人工神经网络的关键。二维(2D)材料具有强的光-物质相互作用和原子薄的悬键无表面,是实现多功能光电子学的候选材料。开发面向未来神经形态应用的二维oeas对于突破冯·诺伊曼架构的瓶颈,实现未来的人工智能系统具有重要意义。本文主要综述了先进二维oeas的最新进展,讨论了它们的工作机制和潜在的应用前景。综述了常用材料、器件结构及其合成和构造方法。最后,从材料、性能和应用等方面对未来二维OEASs的发展前景进行了简要描述。
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