On the half-quantized Hall conductance of massive surface electrons in magnetic topological insulator films

TL;DR

This paper investigates the Hall conductance of surface states in magnetic topological insulator films, revealing that half-quantized conductance arises from gapless bands and is compensated at high energies, challenging previous assumptions.

Contribution

The study demonstrates that half-quantized Hall conductance originates from gapless surface bands and provides an effective model explaining the energy-dependent quantization.

Findings

Gapped surface bands have integer-quantized Hall conductance.

Gapless surface bands exhibit half-quantized Hall conductance at low energy.

Half-quantized conductance is compensated at high energy, consistent with topological constraints.

Abstract

In topological insulators, massive surface bands resulting from local symmetry breaking are believed to exhibit a half-quantized Hall conductance. However, such scenarios are obviously inconsistent with the Thouless-Kohmoto-Nightingale-Nijs theorem, which states that a single band in a lattice with a finite Brillouin zone can only have an integer-quantized Hall conductance. To explore this, we investigate the band structures of a lattice model describing the magnetic topological insulator film that supports the axion insulator, Chern insulator, and semi-magnetic topological insulator phases. We reveal that the gapped and gapless surface bands in the three phases are characterized by an integer-quantized Hall conductance and a half-quantized Hall conductance, respectively. This result is distinct from the previous consensus that the gapped surface band is responsible for the half-quantized Hall conductance and the gapless band should exhibit zero Hall response. We propose an effective model to describe the three phases and show that the low-energy dispersion of the surface bands inherits from the surface Dirac fermions. The gapped surface band manifests a nearly half-quantized Hall conductance at low energy near the center of Brillouin zone, but is compensated by another nearly half-quantized Hall conductance at high energy near the boundary of Brillouin zone because a single band can only have an integer-quantized Hall conductance. The gapless state hosts a zero Hall conductance at low energy but is compensated by another half-quantized Hall conductance at high energy, and thus the half-quantized Hall conductance can only originate from the gapless band. Moreover, we calculate the layer-resolved Hall conductance of the system. The conclusion suggests that the individual gapped surface band alone does not support the half-quantized surface Hall effect in a lattice model.