Exploiting galvanic effect in Ag–Al alloy ion reservoir of resistive switching device for high-density cross-point array memory system

Exploiting galvanic effect in Ag–Al alloy ion reservoir of resistive switching device for high-density cross-point array memory system

A silver (Ag)-based two-terminal semiconductor device exhibits resistive switching behavior driven by Ag+ ion migration. The migration of Ag+ ions, generated through the oxidation of the Ag electrode, forms a Ag filament, resulting in a low-resistance state. Conversely, the outward diffusion of Ag+...

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Bibliographic Details
Main Authors: Seokjae Lim, Jiyong Woo
Format: Article
Language:English
Published: AIP Publishing LLC 2025-05-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/5.0270506
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Summary:A silver (Ag)-based two-terminal semiconductor device exhibits resistive switching behavior driven by Ag+ ion migration. The migration of Ag+ ions, generated through the oxidation of the Ag electrode, forms a Ag filament, resulting in a low-resistance state. Conversely, the outward diffusion of Ag+ ions, caused by the oxidation of neutral Ag within the filament, leads to the dissolution of the filament and a high-resistance state. Typically, in Ag-based two-terminal devices, the filament dissolves when the externally applied voltage is reduced, resulting in volatile threshold-switching characteristics. In this study, we observed that the introduction of an aluminum (Al) layer above or below the Ag electrode increases the electrical energy required for the filament dissolution. The presence of the Al element, which has a lower standard reduction potential than Ag, induces the galvanic effect, which suppresses the generation of Ag+ ions from the Ag filament. This, in turn, raises the electrical energy needed for filament dissolution, resulting in non-volatile memory-switching characteristics. To stabilize the memory-switching characteristics, the optimal amount of Al was explored by creating an Ag–Al alloy ion reservoir via combinatorial sputtering. Based on experimental findings, a resistive switching device with an Ag0.5Al0.5 alloy ion reservoir effectively supplied the optimal amount of Ag+ ions to the HfO2 electrolyte, enhancing the stability of the Ag filament and enabling non-volatile memory-switching. The one-selector–one-resistor (1S–1R) configuration was successfully achieved by depositing pure Ag and Ag0.5Al0.5 ionic reservoirs side-by-side on top of the HfO2 electrolyte, resulting in a monolithically integrated 1S–1R structure.
ISSN:2158-3226

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