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Optically Tunable Electrical Oscillations in Oxide-Based Memristors for Neuromorphic Computing.

Shimul Kanti NathSujan Kumar DasSanjoy Kumar NandiChen XiCamilo Verbel MarquezArmando RúaMutsunori UenumaZhongrui WangSongqing ZhangRui-Jie ZhuJason K EshraghianXiao SunTeng LuYue BianNitu SyedWenwu PanHan WangWen LeiLan FuLorenzo FaraoneYun LiuRobert G Elliman
Published in: Advanced materials (Deerfield Beach, Fla.) (2024)
The application of hardware-based neural networks can be enhanced by integrating sensory neurons and synapses that enable direct input from external stimuli. This work reports direct optical control of an oscillatory neuron based on volatile threshold switching in V 3 O 5 . The devices exhibit electroforming-free operation with switching parameters that can be tuned by optical illumination. Using temperature-dependent electrical measurements, conductive atomic force microscopy (C-AFM), in situ thermal imaging, and lumped element modelling, it is shown that the changes in switching parameters, including threshold and hold voltages, arise from overall conductivity increase of the oxide film due to the contribution of both photoconductive and bolometric characteristics of V 3 O 5 , which eventually affects the oscillation dynamics. Furthermore, V 3 O 5 is identified as a new bolometric material with a temperature coefficient of resistance (TCR) as high as -4.6% K -1 at 423 K. The utility of these devices is illustrated by demonstrating in-sensor reservoir computing with reduced computational effort and an optical encoding layer for spiking neural network (SNN), respectively, using a simulated array of devices.
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