The electrical conductivity of cubic (In1-xGax)2O3 films (x0.18): Native point defects, Sn-doping, and the surface electron accumulation layer

Abstract

The alloying of the group-III transparent semiconducting sesquioxides In2O3 and Ga2O3 can lead to a modulation of the properties of the parent compounds, e.g., the shallow- and deep-donor character of the oxygen vacancy or the presence and absence of a surface electron accumulation layer, respectively. In this work, we investigate the effect of alloying on the electron transport properties of unintentionally-doped single-crystalline and textured bixbyite (In1-xGax)2O3 thin films annealed in oxygen and vacuum with Ga contents up to x=0.18. Hall effect measurements demonstrate a surprising increase in electron density due to native defects with added Ga. This increase may be related to the incorporation of Ga-interstitials or oxygen vacancies induced by Ga-related unit-cell distortions. A combined investigation based on hard and soft x-ray photoelectron spectroscopy measurements demonstrates the existence of the surface electron accumulation layer for all alloy films and, hence, no depletion up to x=0.18. Finally, we additionally demonstrate a single-crystalline (In0.92Ga0.08)2O3:Sn film, as a possible transparent conductive oxide with a wider band gap than that of (Sn-doped) In2O3.