Humidity-mediated synaptic plasticity in Ag loaded porous SiOx based memristor for multimodal neuromorphic sensory system

IF 8.2 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Today Nano Pub Date : 2024-02-19 DOI:10.1016/j.mtnano.2024.100461

Jiaqi Han, Ziyang Yan, Ya Lin, Ye Tao, Xuanyu Shan, Zhongqiang Wang, Xiaoning Zhao, Haiyang Xu, Yichun Liu

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引用次数: 0

Abstract

Neuromorphic sensory system plays a critical role for human being to perceive, interact and even deduce with the external environment. Multimodal plasticity implementation of neuromorphic sensory system that can learn with diversified information empowers the development of environment-interactive artificial intelligence. In this work, we demonstrated a multimodal neuromorphic sensory system based on Ag loaded porous SiO_x based memristor. The humidity-mediated synaptic plasticity behaviors were detailedly analyzed in the range of 10–90% relative humidity (RH). The humidity-mediated silver ion migration in porous SiO_x memristors was studied by theoretical and experimental methods, and the mechanism of synergistic effect between porous micro-structure and ambient humidity was elucidated. A multimodal neuromorphic sensory system was finally constructed and the adaptive behavior of the human eye was also successfully simulated by taking advantage of this well-designed Au/Ag-SiO_x/ITO memristor. The biomimetic intelligence demonstrated in our multimodal neuromorphic sensory devices and systems shows its potential in promoting the advancement in brain-like artificial intelligence.

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用于多模态神经形态传感系统的基于多孔氧化硅的忆阻器中由湿度介导的突触可塑性

神经形态感官系统对人类感知、互动甚至推断外部环境起着至关重要的作用。神经形态感官系统的多模态可塑性实现了对多样化信息的学习，从而推动了环境交互式人工智能的发展。在这项工作中，我们展示了一种基于多孔氧化硅忆阻器的多模态神经形态传感系统。我们详细分析了在相对湿度（RH）10%-90% 范围内湿度介导的突触可塑性行为。通过理论和实验方法研究了湿度介导的银离子在多孔氧化硅忆阻器中的迁移，并阐明了多孔微结构与环境湿度之间的协同效应机制。利用这种精心设计的 Au/Ag-SiOx/ITO Memristor，最终构建了一个多模态神经形态传感系统，并成功模拟了人眼的自适应行为。我们的多模态神经形态传感设备和系统所展示的仿生智能显示了其在促进类脑人工智能发展方面的潜力。

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来源期刊

Materials Today Nano Multiple-

CiteScore

11.30

自引率

3.90%

发文量

130

审稿时长

31 days

期刊介绍： Materials Today Nano is a multidisciplinary journal dedicated to nanoscience and nanotechnology. The journal aims to showcase the latest advances in nanoscience and provide a platform for discussing new concepts and applications. With rigorous peer review, rapid decisions, and high visibility, Materials Today Nano offers authors the opportunity to publish comprehensive articles, short communications, and reviews on a wide range of topics in nanoscience. The editors welcome comprehensive articles, short communications and reviews on topics including but not limited to: Nanoscale synthesis and assembly Nanoscale characterization Nanoscale fabrication Nanoelectronics and molecular electronics Nanomedicine Nanomechanics Nanosensors Nanophotonics Nanocomposites