Low-temperature acanthite-like phase of Cu2S: A first-principles study on electronic and transport properties
Abstract
The mobility and disorder in the lattice of Cu atoms as liquid-like behavior is an important characteristic affecting the thermoelectric properties of Cu2S. In this study, using a theoretical model called acanthite-like structure for Cu2S at a low-temperature range, we systematically investigate the electronic structure, intrinsic defect formation, and transport properties by first-principles calculations. Thereby, previous experimental reports on the indirect bandgap nature of Cu2S were confirmed in this work with an energy gap of about 0.9-0.95 eV. As a result, the optical absorption coefficient estimated from this model also gives a potential value of α > 104 cm-1 in the visible spectrum range. According to the bonding analysis and formation energy aspect, Cu vacancy is the most preferred defect to form in Cu2S, which primarily affects the conductive behavior as a p-type, as experimentally observed. Finally, the transport properties of Cu2S system were successfully reproduced using an electron-phonon scattering method, highlighting the important role of relaxation time prediction in conductivity estimation instead of regarding it as a constant.
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