Analyticity and symmetry of band extrema in gapped solids: when does the effective mass approximation hold?

Abstract

The effective mass approximation is widely used across models of carrier transport, optical response, and excitons in semiconductors and insulators, but its validity hinges on the assumption that the band dispersion En(k) at the relevant extremum is analytic. We prove that analyticity holds at any non-degenerate extremum for the standard ab initio Hamiltonians, including density functional theory with local or hybrid exchange-correlation functionals and for band-edge G0W0 quasiparticle energies in gapped systems. Band non-analyticity (or warping) in these settings is therefore intrinsically tied to degeneracy. We then use group theory to determine the symmetry-allowed form of the effective mass tensor for each of the 32 crystallographic point groups, providing a stringent consistency check on first-principles calculations. As a representative application, we show that the electron and hole effective masses at the K point of monolayer MoS2 must be strictly isotropic at the DFT and G0W0 levels.