# Spatially uniform resistance switching of low current, high endurance   titanium-niobium-oxide memristors

**Authors:** Suhas Kumar, Noraica Davila, Ziwen Wang, Xiaopeng Huang, John Paul, Strachan, David Vine, A. L. David Kilcoyne, Yoshio Nishi, R. Stanley Williams

arXiv: 1701.01784 · 2017-01-10

## TL;DR

This study demonstrates that titanium-niobium-oxide memristors operate with spatially uniform resistance switching, exhibiting low power consumption, high endurance, and providing insights into their physico-chemical mechanisms for improved device design.

## Contribution

The paper reveals that titanium-niobium-oxide memristors switch resistance uniformly without localized channels, contrasting with typical transition-metal-oxide memristors, and links spectral features to their operation mechanisms.

## Key findings

- Low write-power (<3 μW) and energy (<200 fJ/bit/μm^2)
- High endurance (>millions of cycles)
- Spatially uniform material changes during operation

## Abstract

We analyzed micrometer-scale titanium-niobium-oxide prototype memristors, which exhibited low write-power (<3 {\mu}W) and energy (<200 fJ/bit/{\mu}m2), low read-power (~nW), and high endurance (>millions of cycles). To understand their physico-chemical operating mechanisms, we performed in-operando synchrotron x-ray transmission nanoscale spectromicroscopy using an ultra-sensitive time-multiplexed technique. We observed only spatially uniform material changes during cell operation, in sharp contrast to the frequently detected formation of a localized conduction channel in transition-metal-oxide memristors. We also associated the response of assigned spectral features distinctly to non-volatile storage (resistance change) and writing of information (application of voltage and Joule heating). These results provide critical insights into high-performance memristors that will aid in device design, scaling and predictive circuit-modeling, all of which are essential for the widespread deployment of successful memristor applications.

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Source: https://tomesphere.com/paper/1701.01784