The electronic structure of β-HgS via GW calculations

Abstract

The electronic structure of the zincblende β-HgS is not well understood. Previous first-principles calculations using fully-relativistic density functional theory and many-body perturbation theory in the fully-relativistic GW approach have predicted an inverted, topologically non-trivial ordering of these states, with the s-like 6 state occupied. However, other calculations using the GW approach in which spin-orbit coupling is added perturbatively ("GW+SOC") predict the p-d hybridized 7 and 8 states to be occupied and the 6 state to be unoccupied, suggesting that β-HgS is a topologically trivial small band gap semiconductor. In the present work, a plane-wave pseudopotential fully-relativistic GW calculation finds a band ordering in agreement with the previous GW+SOC calculations. The calculated band gap is 0.10 eV and the electron effective mass is 0.07 me, in good agreement with experiment.