Accuracy of GW for calculating defect energy levels in solids

The accuracy of GW in the determination of defect energy levels is assessed through calculations on a set of well-characterized point defects in semiconductors: the As antisite in GaAs, the substitutional Mg in GaN, the interstitial C in Si, the Si dangling bond, and the Si split-vacancy complex in diamond. We show that the GW scheme achieves a reliable description of charge transition levels, but the overall accuracy is comparable to that of hybrid-functional calculations.

Accuracy of GW for calculating defect energy levels in solids

Graph Chatbot

Accelerating the theoretical study of Li-polysulfide adsorption on single-atom catalysts via machine learning approaches

Stoichiometry modulates the optoelectronic functionality of Zinc Phosphide (Zn3-xP2+x)

Pivotal Role of Intersite Hubbard Interactions in Fe-Doped alpha-MnO2

Stoichiometry modulates the optoelectronic functionality of Zinc Phosphide (Zn3-xP2+x)

Pivotal Role of Intersite Hubbard Interactions in Fe-Doped alpha-MnO2

Accelerating the theoretical study of Li-polysulfide adsorption on single-atom catalysts via machine learning approaches