突触可塑性
长时程增强
材料科学
突触
突触重量
突触增强
钙钛矿(结构)
多巴胺
神经科学
非突触性可塑性
光电子学
变质塑性
计算机科学
人工神经网络
人工智能
化学
生物
生物化学
结晶学
受体
作者
Seonggil Ham,Sanghyeon Choi,Haein Cho,Seok‐In Na,Gunuk Wang
标识
DOI:10.1002/adfm.201806646
摘要
Abstract The ability of high‐order tuning of the synaptic plasticity in an artificial synapse can offer significant improvement in the processing time, low‐power recognition, and learning capability in a neuro‐inspired computing system. Inspired by light‐assisted dopamine‐facilitated synaptic activity, which achieves rapid learning and adaptation by lowering the threshold of the synaptic plasticity, a two‐terminal organolead halide perovskite (OHP)‐based photonic synapse is fabricated and designed in which the synaptic plasticity is modified by both electrical pulses and light illumination. Owing to the accelerated migration of the iodine vacancy inherently existing in the coated OHP film under light illumination, the OHP synaptic device exhibits light‐tunable synaptic functionalities with very low programming inputs (≈0.1 V). It is also demonstrated that the threshold of the long‐term potentiation decreases and synaptic weight further modulates when light illuminates the device, which is phenomenologically analogous to the dopamine‐assisted synaptic process. Notably, under light exposure, the OHP synaptic device achieves rapid pattern recognition with ≈81.8% accuracy after only 2000 learning phases (60 000 learning phases = one epoch) with a low‐power consumption (4.82 nW/the initial update for potentiation), which is ≈2.6 × 10 3 times lower than when the synaptic weights are updated by only high electrical pulses.
科研通智能强力驱动
Strongly Powered by AbleSci AI