Harnessing Earth‐Abundant Lead‐Free Halide Perovskite for Resistive Switching Memory and Neuromorphic Computing
Zijian Feng, Jiyun Kim, Jie Min, Peiyuan Guan, Shuo Zhang, Xinwei Guan, Tingting Mei, Tianxu Huang, Chun‐Ho Lin, Long Hu, Fandi Chen, Zhi Li, Jiabao Yi, Tom Wu, Dewei Chu
Abstract
Abstract Non‐volatile memories are expected to revolutionize a wide range of information technologies, but their manufacturing cost is one of the top concerns researchers must address. This study presents a 1D lead‐free halide perovskite K 2 CuBr 3 , as a novel material candidate for the resistive switching (RS) devices, which features only earth‐abundant elements, K, Cu, and Br. To the knowledge, this material is the first low‐dimensional halide perovskite with exceptionally low production costs and minimal environmental impact. Owing to the unique 1D carrier transport along the Cu─Br networks, the K 2 CuBr 3 RS device exhibits excellent bipolar switching behavior, with an On/Off window of 10 5 and a retention time of over 1000 s. The K 2 CuBr 3 RS devices can also act as artificial synapses to transmit various forms of synaptic plasticities, and their integration into a perceptron artificial neural network can deliver a high algorithm accuracy of 93% for image recognition. Overall, this study underscores the promising attributes of K 2 CuBr 3 for the future development of memory storage and neuromorphic computing, leveraging its distinct material properties and economic benefits.