Resistance-Restorable Nanofluidic Memristor and Neuromorphic Chip

Ke Liu; Yongchang Wang; Miao Sun; Jiajia Lu; Deli Shi; Yanbo Xie

doi:10.1021/acs.nanolett.5c00315

Resistance-Restorable Nanofluidic Memristor and Neuromorphic Chip

Ke Liu
, Yongchang Wang
, Miao Sun
, Jiajia Lu
, Deli Shi
, Yanbo Xie

航空学院

Northwestern Polytechnical University Xian

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

Resistance drift due to residual ions limits the accuracy of memristor-based neuromorphic computing. Here, we demonstrate nanofluidic memristors based on voltage-driven ion filling within Ångström channels, immersed in asymmetrically concentrated electrolyte solutions. Inspired by the brain’s waste clearance, we restore conductance after 20,000 cycles by removing trapped ions, paving the way for endurance enhancement. The devices exhibit hour-long retention and ultralow energy consumption (∼0.2 fJ per spike per channel). By tuning the voltage, frequency, and pH, we emulate short-term synaptic plasticity. Finally, we demonstrated the first 4 × 4 nanofluidic memristor array capable of recognizing mathematical operators. Our work demonstrated that fluidic memristors are promising for energy-efficient, long-retention, and endurance neuromorphic chips.

源语言	英语
期刊	Nano Letters
DOI	https://doi.org/10.1021/acs.nanolett.5c00315
出版状态	已接受/待刊 - 2025

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10.1021/acs.nanolett.5c00315

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引用此

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title = "Resistance-Restorable Nanofluidic Memristor and Neuromorphic Chip",

abstract = "Resistance drift due to residual ions limits the accuracy of memristor-based neuromorphic computing. Here, we demonstrate nanofluidic memristors based on voltage-driven ion filling within {\AA}ngstr{\"o}m channels, immersed in asymmetrically concentrated electrolyte solutions. Inspired by the brain{\textquoteright}s waste clearance, we restore conductance after 20,000 cycles by removing trapped ions, paving the way for endurance enhancement. The devices exhibit hour-long retention and ultralow energy consumption (∼0.2 fJ per spike per channel). By tuning the voltage, frequency, and pH, we emulate short-term synaptic plasticity. Finally, we demonstrated the first 4 × 4 nanofluidic memristor array capable of recognizing mathematical operators. Our work demonstrated that fluidic memristors are promising for energy-efficient, long-retention, and endurance neuromorphic chips.",

keywords = "ANN, Fluidic circuitry, Iontronics, Memristor, Nanofluidics, Neuromorphic chip",

author = "Ke Liu and Yongchang Wang and Miao Sun and Jiajia Lu and Deli Shi and Yanbo Xie",

note = "Publisher Copyright: {\textcopyright} 2025 American Chemical Society.",

year = "2025",

doi = "10.1021/acs.nanolett.5c00315",

language = "英语",

journal = "Nano Letters",

issn = "1530-6984",

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AU - Liu, Ke

AU - Wang, Yongchang

AU - Sun, Miao

AU - Lu, Jiajia

AU - Shi, Deli

AU - Xie, Yanbo

PY - 2025

Y1 - 2025

N2 - Resistance drift due to residual ions limits the accuracy of memristor-based neuromorphic computing. Here, we demonstrate nanofluidic memristors based on voltage-driven ion filling within Ångström channels, immersed in asymmetrically concentrated electrolyte solutions. Inspired by the brain’s waste clearance, we restore conductance after 20,000 cycles by removing trapped ions, paving the way for endurance enhancement. The devices exhibit hour-long retention and ultralow energy consumption (∼0.2 fJ per spike per channel). By tuning the voltage, frequency, and pH, we emulate short-term synaptic plasticity. Finally, we demonstrated the first 4 × 4 nanofluidic memristor array capable of recognizing mathematical operators. Our work demonstrated that fluidic memristors are promising for energy-efficient, long-retention, and endurance neuromorphic chips.

AB - Resistance drift due to residual ions limits the accuracy of memristor-based neuromorphic computing. Here, we demonstrate nanofluidic memristors based on voltage-driven ion filling within Ångström channels, immersed in asymmetrically concentrated electrolyte solutions. Inspired by the brain’s waste clearance, we restore conductance after 20,000 cycles by removing trapped ions, paving the way for endurance enhancement. The devices exhibit hour-long retention and ultralow energy consumption (∼0.2 fJ per spike per channel). By tuning the voltage, frequency, and pH, we emulate short-term synaptic plasticity. Finally, we demonstrated the first 4 × 4 nanofluidic memristor array capable of recognizing mathematical operators. Our work demonstrated that fluidic memristors are promising for energy-efficient, long-retention, and endurance neuromorphic chips.

KW - ANN

KW - Fluidic circuitry

KW - Iontronics

KW - Memristor

KW - Nanofluidics

KW - Neuromorphic chip

UR - https://www.scopus.com/pages/publications/105002673296

U2 - 10.1021/acs.nanolett.5c00315

DO - 10.1021/acs.nanolett.5c00315

M3 - 文章

AN - SCOPUS:105002673296

SN - 1530-6984

JO - Nano Letters

JF - Nano Letters

ER -

Resistance-Restorable Nanofluidic Memristor and Neuromorphic Chip

摘要

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