Bifunctional Memristive Behavior of a Dual‐Layer Structure Depending on the Configuration of Charge Transport

Bifunctional Memristive Behavior of a Dual‐Layer Structure Depending on the Configuration of Charge Transport

Abstract This paper presents a method for integrating neuronal and synaptic functions within a thin dual‐layer featuring distinct dielectric strengths. The dual‐layer consists of a conductive bottom layer (e.g., MXenes or rGOs) and a top layer with a lower dielectric strength (e.g., gallium oxide)....

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Bibliographic Details
Main Authors: Suji Ha, YoungJu Park, Chanjin Lim, Eunyeong Yang, Taegil Kim, Seon Joon Kim, Junwoo Park
Format: Article
Language:English
Published: Wiley-VCH 2025-08-01
Series:Advanced Electronic Materials
Subjects:
artificial neuron
artificial synapse
charge transport
conductance switching
neuromorphic computing
Online Access:https://doi.org/10.1002/aelm.202500029
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Summary:Abstract This paper presents a method for integrating neuronal and synaptic functions within a thin dual‐layer featuring distinct dielectric strengths. The dual‐layer consists of a conductive bottom layer (e.g., MXenes or rGOs) and a top layer with a lower dielectric strength (e.g., gallium oxide). The differing dielectric strengths between the layers facilitate the modulation of breakdown, as the magnitude of the electric field applied in one layer varies with the configuration of charge transport in the other layer. In a vertical configuration, the dual‐layer exhibits volatile and abrupt switching (neuronal behavior), while in a horizontal configuration, it demonstrates non‐volatile and gradual changes in conductance (synaptic behavior). The experimental results indicate that the abrupt switching is attributed to filament formation, while the gradual change in conductance arises from charge transport in gallium oxide. The dual‐layer shows the characteristics of integrate‐and‐fire depending on spiking signals with synaptic plasticity and achieves training accuracies of 91.4% and 82.3% for MNIST digit classification based on MXene and rGO, respectively.
ISSN:2199-160X

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