# Electronic conduction properties of indium tin oxide: single-particle   and many-body transport

**Authors:** Juhn-Jong Lin, Zhi-Qing Li

arXiv: 1702.07845 · 2017-03-29

## TL;DR

This paper investigates the fundamental electronic conduction mechanisms of indium tin oxide (ITO) across a wide temperature range, revealing rich physics including quantum interference, electron-electron interactions, and the effects of disorder in various ITO structures.

## Contribution

It provides a comprehensive analysis of ITO's electronic transport properties from 300 K to low temperatures, highlighting new physics phenomena and the influence of microscopic parameters.

## Key findings

- Rich quantum-interference effects observed in ITO
- Electron-electron interactions significantly influence conduction
- Low carrier concentration leads to slow electron-phonon relaxation

## Abstract

Indium tin oxide (Sn-doped In$_2$O$_{3-\delta}$ or ITO) is an interesting and technologically important transparent conducting oxide. This class of material has been extensively studied for decades, with research efforts focusing on the application aspects. The fundamental issues of the electronic conduction properties of ITO from 300 K down to low temperatures have rarely been addressed. Studies of the electrical-transport properties over a wide range of temperature are essential to unraveling the underlying electronic dynamics and microscopic electronic parameters. We show that one can learn rich physics in ITO material, including the semi-classical Boltzmann transport, the quantum-interference electron transport, and the electron-electron interaction effects in the presence of disorder and granularity. To reveal the opportunities that the ITO material provides for fundamental research, we demonstrate a variety of charge transport properties in different forms of ITO structures, including homogeneous polycrystalline films, homogeneous single-crystalline nanowires, and inhomogeneous ultrathin films. We not only address new physics phenomena that arise in ITO but also illustrate the versatility of the stable ITO material forms for potential applications. We emphasize that, microscopically, the rich electronic conduction properties of ITO originate from the inherited free-electron-like energy bandstructure and low-carrier concentration (as compared with that in typical metals) characteristics of this class of material. Furthermore, a low carrier concentration leads to slow electron-phonon relaxation, which causes ($i$) a small residual resistance ratio, ($ii$) a linear electron diffusion thermoelectric power in a wide temperature range 1-300 K, and ($iii$) a weak electron dephasing rate. We focus our discussion on the metallic-like ITO material.

## Full text

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## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/1702.07845/full.md

## References

190 references — full list in the complete paper: https://tomesphere.com/paper/1702.07845/full.md

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Source: https://tomesphere.com/paper/1702.07845