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Main Authors: Zhou, Wenzhe, Ge, Dongjiao, Zhang, Ao, Xu, Jincheng, Ji, Yu, Gong, Yiran, Zhang, Wenchang, Li, Jidong, Lin, Li, Xu, Zhiping, Sun, Pengzhan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.19228
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author Zhou, Wenzhe
Ge, Dongjiao
Zhang, Ao
Xu, Jincheng
Ji, Yu
Gong, Yiran
Zhang, Wenchang
Li, Jidong
Lin, Li
Xu, Zhiping
Sun, Pengzhan
author_facet Zhou, Wenzhe
Ge, Dongjiao
Zhang, Ao
Xu, Jincheng
Ji, Yu
Gong, Yiran
Zhang, Wenchang
Li, Jidong
Lin, Li
Xu, Zhiping
Sun, Pengzhan
contents Nanofluidic memristive devices work with nanoscale pores and ions dissolved in water, which harness the ionic memory effect aiming to store and process information. These devices share the same charge carriers as biological systems and bring hope for better emulating the neural functions and developing ionic circuits for neuromorphic applications. Specially, theory and experiments suggest that nanoconfinement is essential for inducing a memory effect, which places limit on the pore size to nm-scale or smaller. Such devices are difficult to scale up with precision and operate with long-term stability. Here, we show that a micrometer size pore, generally expected to exhibit a linear ion transport, can display a pronounced memory effect, if its rim is wrapped by strongly curved and tightly stacked graphene. We attribute the observation to slow ion dynamics confined in the rippled graphene edges. The devices are easy to scale up and integrate into fluidic circuits. The memory effect is ion-selective and exhibits long endurance comparable to the lifetime of synaptic proteins, which enables reversible modification of the conductance states using programmable voltage spikes and various electrolytes over a long time, akin to biological synaptic plasticity. Thanks to this plasticity, our devices and their integrated circuits enable storing, transmitting and processing information with high reliability, fidelity and accuracy, as evidenced in the identification of both greyscale and color images, and in the real-time analysis of emulated neural signals. Our results highlight nanoscale morphology of the pore wall as an important parameter regulating ion transport and indicate that the stringent nanoconfinement for ionic memory can be lifted from restricting the pore size to designing its rim structure. The devices and their integrated circuits may find use in ionic neuromorphic applications.
format Preprint
id arxiv_https___arxiv_org_abs_2604_19228
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Rippled graphene pores as fluidic memristive devices with synaptic and neuromorphic functionalities
Zhou, Wenzhe
Ge, Dongjiao
Zhang, Ao
Xu, Jincheng
Ji, Yu
Gong, Yiran
Zhang, Wenchang
Li, Jidong
Lin, Li
Xu, Zhiping
Sun, Pengzhan
Materials Science
Nanofluidic memristive devices work with nanoscale pores and ions dissolved in water, which harness the ionic memory effect aiming to store and process information. These devices share the same charge carriers as biological systems and bring hope for better emulating the neural functions and developing ionic circuits for neuromorphic applications. Specially, theory and experiments suggest that nanoconfinement is essential for inducing a memory effect, which places limit on the pore size to nm-scale or smaller. Such devices are difficult to scale up with precision and operate with long-term stability. Here, we show that a micrometer size pore, generally expected to exhibit a linear ion transport, can display a pronounced memory effect, if its rim is wrapped by strongly curved and tightly stacked graphene. We attribute the observation to slow ion dynamics confined in the rippled graphene edges. The devices are easy to scale up and integrate into fluidic circuits. The memory effect is ion-selective and exhibits long endurance comparable to the lifetime of synaptic proteins, which enables reversible modification of the conductance states using programmable voltage spikes and various electrolytes over a long time, akin to biological synaptic plasticity. Thanks to this plasticity, our devices and their integrated circuits enable storing, transmitting and processing information with high reliability, fidelity and accuracy, as evidenced in the identification of both greyscale and color images, and in the real-time analysis of emulated neural signals. Our results highlight nanoscale morphology of the pore wall as an important parameter regulating ion transport and indicate that the stringent nanoconfinement for ionic memory can be lifted from restricting the pore size to designing its rim structure. The devices and their integrated circuits may find use in ionic neuromorphic applications.
title Rippled graphene pores as fluidic memristive devices with synaptic and neuromorphic functionalities
topic Materials Science
url https://arxiv.org/abs/2604.19228