Geometric mass acquisition via quantum metric: an effective band mass theorem for the helicity bands

Abstract

By taking the virtual inter-band transitions along with the intra-band ones into full account, here we first propose an effective band mass theorem that is suitable for a wide-class of single-particle Hamiltonians exhibiting multiple energy bands. Then, for the special case of two-band systems, we show that the inter-band contribution to the effective band mass of a particle at a given quantum state is directly controlled by the quantum metric of the corresponding state. As an illustration, we consider a spin-orbit coupled spin-1/2 particle and calculate its effective band mass at the band minimum of the lower helicity band. Independent of the coupling strength, we find that the bare mass m0 of the particle jumps to 2m0 for the Rashba and to 3m0 for the Weyl coupling. This geometric mass enhancement is a non-perturbative effect, uncovering the mystery behind the effective mass of the two-body bound states in the non-interacting limit. As a further illustration, we show that a massless Dirac particle acquires a linearly dispersing band mass (equivalent to the effective cyclotron one up to a prefactor) with its momentum through the same mechanism.