Crystal structure prediction of three- and two-dimensional Ga2O3 using a multi-objective differential evolution algorithm

Abstract

Wide-band-gap semiconductor gallium oxide (Ga₂O₃) has significant advantages for use in high-power semiconductor devices and deep-ultraviolet-detection optoelectronic devices. Crystal structure prediction is one of the most challenging and interesting issues in condensed matter science. In this work, 11 three-dimensional (3D) Ga₂O₃ structures and four two-dimensional (2D) Ga₂O₃ structures were predicted and screened based on a multi-objective differential evolution algorithm combined with density functional theory (DFT) calculations. Two low-energy 3D structures proved to be consistent with previously characterized β-Ga₂O₃ (C2/m) and α-Ga₂O₃ (Rc). Their stabilities were confirmed by calculation of their structural parameters, phonon spectra, elastic constants, and elastic moduli. Their photoelectric properties were also investigated. The results showed that both the stable 3D and 2D Ga₂O₃ structures had wide band gaps, and some of them exhibited good optical properties. These findings are of great significance in providing theoretical guidance for the structural design of Ga₂O₃ materials and their application in microelectronic and photoelectric devices.