# Energetics and electronic structure of native point defects in   ${\alpha}$-Ga2O3

**Authors:** Takuma Kobayashi, Tomoya Gake, Yu Kumagai, Fumiyasu Oba, Yu-ichiro, Matsushita

arXiv: 1906.03765 · 2019-08-13

## TL;DR

This study uses first-principles calculations to analyze native point defects in ${m oldsymbol{eta}}$-Ga2O3, revealing how defect formation energies and charge states influence doping and electronic properties under different growth conditions.

## Contribution

It provides detailed insights into defect energetics and charge transition levels in ${m oldsymbol{eta}}$-Ga2O3, guiding doping strategies for electronic applications.

## Key findings

- Negatively-charged Ga vacancy dominates near conduction band edge.
- Positively-charged Ga interstitial dominates near valence band edge.
- Ga-rich conditions favor n-type doping by suppressing Ga vacancy formation.

## Abstract

We report first-principles calculations that clarify the formation energies and charge transition levels of native point defects (Ga and O vacancies, interstitials, and a Ga vacancy-O vacancy pair) in corundum structured ${\alpha}$-Ga2O3. Either under a Ga- or O-rich growth condition, the negatively-charged Ga vacancy and the positively-charged Ga interstitial on a site surrounded by six O atoms are dominant when the Fermi level approaches the conduction and valence band edges, respectively. These defects would compensate carrier electrons and holes, respectively. Ga-rich conditions relatively suppress the formation of the Ga vacancy and, therefore, are suited for extrinsic n-type doping of ${\alpha}$-Ga2O3.

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Source: https://tomesphere.com/paper/1906.03765