神经形态工程学
光探测
纳米线
材料科学
异质结
光电子学
光子学
纳米技术
半导体
载流子
碳纳米管
计算机科学
纳米电子学
电子工程
石墨烯
太赫兹辐射
电子迁移率
发光二极管
逻辑门
作者
Zhenwei Guo,Yue He,Haoming Wei,Dayong Jiang,Man Zhao,Liang Liang,Wei Yang
标识
DOI:10.1002/lpor.202502268
摘要
ABSTRACT Engineering semiconductor heterojunctions is a pivotal research frontier for developing next‐generation optoelectronic devices, particularly for neuromorphic computing. However, performing precise, stimulus‐selective control over interfacial carrier dynamics to unlock advanced memory and logic functions remains a significant challenge. Herein, we unveil a novel “photon‐energy‐gated selective carrier accumulation” mechanism within macroscopically ordered ZnO/Ga 2 O 3 core–shell nanowire heterojunctions, governed by the Type‐I band alignment at the heterointerface. This unique architecture, fabricated via a super‐aligned carbon nanotube template, not only boosts the UV photoresponsivity by 78‐fold compared to pure ZnO counterparts but also enables a remarkable wavelength‐selective activation of persistent photoconductivity. Harnessing this optically switchable memory effect, we demonstrate its application in optoelectronic synaptic devices, and we also prove its potential in physical reservoir computing system, achieving a high classification accuracy of 87.9% on the Fashion ‐ Modified National Institute of Standards and Technology (F‐MNIST) dataset. This study provides a new paradigm for designing intelligent optoelectronic devices by precisely manipulating interfacial carrier dynamics, opening promising avenues for in‐sensor computing and advanced photonic memory.
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