神经形态工程学
记忆电阻器
材料科学
纳米技术
人工神经网络
纳米尺度
尖峰神经网络
计算机科学
MNIST数据库
突触
机制(生物学)
长时程增强
人工智能
仿生学
纳米电子学
离子通道
物理神经网络
编码(内存)
电导
光子学
生物系统
生物神经网络
离子
生物电子学
钥匙(锁)
电压
物理
记忆晶体管
油藏计算
非易失性存储器
突触可塑性
作者
Muhammad Jahangeer,Jinlong Guo,Zhaoyang Qin,Chenyu Li,W. J. Liu,Can Zhao,Wenchang Zhou,Hongjin Mou,Ruqun Wu,Cheng Shen,Linyan Fu,Baobei Li,Muhammad Faisal Junaid,H. F. Yao,Qi Wang,Guanghua Du
标识
DOI:10.1002/adfm.202525932
摘要
ABSTRACT Memory and learning in biological systems arise from ion transport across nanoscale synaptic junctions in neural networks. These junctions act as a natural memristors and thus, reproducing this effect in artificial aqueous systems is crucial for mimicking neural functions and advancing neuromorphic computing. Herein, we successfully demonstrated the memristive effects through the spatial confinement of water and ions within a biomimetic nanochannel, using two distinct stimulation mechanisms (i) divalent‐ion screening and (ii) pH‐driven deprotonation. In both cases, broken symmetry within the medium coupled with surface effects, lead to hysteretic ion transport. This nanofluidic memristor also emulated biological memory features, including both short/long‐term potentiation and key synaptic functionalities, such as paired‐pulse facilitation (PPF) and paired‐pulse depression (PPD). The reversible modulation of ionic conductance of our nanofluidic device enabled dynamic encoding of synaptic weights, a key mechanism underlying adaptive learning behavior in neuromorphic systems. Leveraging this property, a three‐layer artificial neural network for pattern recognition is trained and recognition accuracy of 94.6% on the small‐digit MNIST dataset, which can compete with the performance of many solid‐state memristive synapses. The memory effect resemblance between our single‐channel system to biological counterparts, paves the way for elucidating the origin of memory in biological systems and advancing nanofluidic memristor‐based neuromorphic computing.
科研通智能强力驱动
Strongly Powered by AbleSci AI