What question did this study set out to answer?

The research aims to explore the resistive switching properties of memristive structures using specific nanocomposite and dielectric materials.

March 26, 2026

Resistive Switching of Memristors Based on (CoFe)x(SiO2)100–x Nanocomposite and LiNbO3 Layers with Ni Electrode

Key Points

The research aims to explore the resistive switching properties of memristive structures using specific nanocomposite and dielectric materials.
Investigation of Cu/NC/D/Ni memristive structures with varying nanocomposite and dielectric layers.
Annealing of samples at 300°C for 10 minutes.
Measurement of high-resistance state and low-resistance state ratios.
Annealing increases the Roff to Ron ratio and enhances the stability of the resistive state.
Greater thickness of the LiNbO3 layer correlates with increased Roff, Ron, and RS voltage.
Memristors demonstrate stable multilevel resistive switching over multiple cycles.

Abstract

The properties of Cu/NC/D/Ni memristive structures with thin layers of (CoFe)x(SiO2)100–x nanocomposite (230 nm) and LiNbO3 dielectric (14–28 nm) are studied. It is shown that annealing the structures at 300°C for 10 min leads to increase in the ratio of the high-resistance state (Roff) to the low-resistance state (Ron). Heat treatment also increases the stability of resistive state. The increase of the LiNbO3 layer thickness increases in the values of Roff, Ron, and the resistive switching (RS) voltage of the structures to the low-resistance state. The structures exhibit stable multilevel RS in successive cycles of potentiation and depression, which, coupled with plasticity and a high Roff/Ron ratio, demonstrates the prospects of their use as synapses in the development of neuromorphic systems.

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Cite This Study

Nikolaev et al. (Mon,) studied this question.

synapsesocial.com/papers/69c4cc37fdc3bde44891773d https://doi.org/https://doi.org/10.1134/s1063739725601122

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