Issue 11, 2019

Universal 1/f type current noise of Ag filaments in redox-based memristive nanojunctions

Abstract

The microscopic origins and technological impact of 1/f type current fluctuations in Ag based, filamentary type resistive switching devices have been investigated upon downscaling toward the ultimate single atomic limit. The analysis of the low-frequency current noise spectra revealed that the main electronic noise contribution arises from the resistance fluctuations due to internal dynamical defects of Ag nanofilaments. The resulting 0.01–1% current noise ratio, i.e. the total noise level with respect to the mean value of the current, is found to be universal: its magnitude only depends on the total resistance of the device, irrespective of the materials aspects of the surrounding solid electrolyte and of the specific filament formation procedure. Moreover, the resistance dependence of the current noise ratio also displays the diffusive to ballistic crossover, confirming that stable resistive switching operation utilizing Ag nanofilaments is not compromised even in truly atomic scale junctions by technologically impeding noise levels.

Graphical abstract: Universal 1/f type current noise of Ag filaments in redox-based memristive nanojunctions

Article information

Article type
Communication
Submitted
10 Dec 2018
Accepted
19 Feb 2019
First published
19 Feb 2019
This article is Open Access
Creative Commons BY-NC license

Nanoscale, 2019,11, 4719-4725

Universal 1/f type current noise of Ag filaments in redox-based memristive nanojunctions

B. Sánta, Z. Balogh, A. Gubicza, L. Pósa, D. Krisztián, G. Mihály, M. Csontos and A. Halbritter, Nanoscale, 2019, 11, 4719 DOI: 10.1039/C8NR09985E

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