Computational and experimental approach for investigation of electronic and optical response of MgxCu2-xO

Abstract

The electronic and optical characteristics of Cu2O based semiconductor materials are recently focused on due to having applications in modern electronic devices and solar cells. In this study, Mg incorporated Cu2O structures were simulated using density functional theory calculations for the prediction of electronic and optical response. The simulations were carried out using the generalized gradient approximation approach by considering the full-potential linearized augmented plane wave method. Pure and Mg incorporated Cu2O thin films with 3.7, 5.5, and 12.5% Mg contents were deposited in uniform morphology using spin coating technique. Ab-initio and experimental investigations present a strong correlation of electronic and optical properties. The bandgap was observed to decrease with the incorporation of Mg in the Cu2O structure. The absorption coefficient and real epsilon depict a sharp increment with Mg doping in the visible regime. The specific outcomes make these materials excellent candidates for dielectric and optoelectronic applications.