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In‐Memory Computing using Memristor Arrays with Ultrathin 2D PdSeO<i><sub>x</sub></i>/PdSe<sub>2</sub> Heterostructure

Yesheng LiDepartment of Electrical and Computer Engineering National University of Singapore 4 Engineering Drive 3 Singapore 117583 SingaporeShuai ChenInstitute for High Performance Computing A*STAR 1 Fusionopolis Way Singapore 138632 SingaporeZhigen YuInstitute for High Performance Computing A*STAR 1 Fusionopolis Way Singapore 138632 SingaporeSifan LiDepartment of Electrical and Computer Engineering National University of Singapore 4 Engineering Drive 3 Singapore 117583 SingaporeYao XiongDepartment of Physics School of Science Wuhan University of Technology Wuhan 430070 ChinaMer‐Er PamDepartment of Electrical and Computer Engineering National University of Singapore 4 Engineering Drive 3 Singapore 117583 SingaporeYong‐Wei ZhangInstitute for High Performance Computing A*STAR 1 Fusionopolis Way Singapore 138632 SingaporeKah‐Wee AngDepartment of Electrical and Computer Engineering National University of Singapore 4 Engineering Drive 3 Singapore 117583 Singapore
2022en
ABI

Annotatsiya

Abstract In‐memory computing based on memristor arrays holds promise to address the speed and energy issues of the classical von Neumann computing system. However, the stochasticity of ions’ transport in conventional oxide‐based memristors imposes severe intrinsic variability, which compromises learning accuracy and hinders the implementation of neural network hardware accelerators. Here, these challenges are addressed using a low‐voltage memristor array based on an ultrathin PdSeO x /PdSe 2 heterostructure switching medium realized by a controllable ultraviolet (UV)–ozone treatment. A distinctively different ions’ transport mechanism is revealed in the heterostructure that can confine the formation of conductive filaments, leading to a remarkable uniform switching with low set and reset voltage variability values of 4.8% and −3.6%, respectively. Moreover, convolutional image processing is further implemented using various crossbar kernels that achieve a high recognition accuracy of ≈93.4% due to the highly linear and symmetric analog weight update as well as multiple conductance states, manifesting its potential beyond von Neumann computing.

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