神经形态工程学
记忆电阻器
纳米技术
材料科学
纳米电子学
电阻随机存取存储器
纳米尺度
电阻式触摸屏
频道(广播)
钥匙(锁)
计算机科学
电子工程
导电体
电导
电气工程
光电子学
机制(生物学)
工程物理
功率(物理)
CMOS芯片
热传导
逻辑门
工程类
新兴技术
作者
Xiaohan Zhang,Xuanyu Shan,Xiaoning Zhao,Ya Lin,Ye Tao,Zhongqiang Wang,Haiyang Xu,Yichun Liu
摘要
Electrochemical metallization (ECM) memristors, with their advantages of high ON/OFF ratio, fast switching speeds, and low power consumption, have shown broad prospects in emerging applications such as neuromorphic computing, low-power logic computing, and artificial intelligence hardware. To fully realize the potential of ECM memristors, it is necessary to gain a deep understanding of the complexity of ion migration and redox reactions associated with resistive switching at the nanoscale. This review first systematically elucidates the resistive switching mechanism of ECM memristors, then focuses on discussing various novel physical effects emerging at the nanoscale, including the nanobattery effect, quantized conductance effect, diffusion effect, photo-induced resistive switching effect, and bio-voltage effect. A further review of the latest application advancements of these effects in cutting-edge fields such as artificial synapses, bioelectronic interfaces, in-memory computing, and neuromorphic perception. Finally, we explored the key challenges and potential opportunities facing ECM memristors in their future development, aiming to lay the groundwork for future neuromorphic computing research.
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