Magnetization-Induced Phase Transitions on the surface of 3D Topological Insulators

TL;DR

This paper demonstrates surface magnetization induces phase transitions in 3D topological insulators, causing quantized changes in surface Chern numbers and observable magneto-electric effects, revealing new phases and broken bulk-boundary correspondence.

Contribution

It introduces a realistic lattice model showing surface phase transitions and Chern number changes in 3D TIs due to magnetization, expanding understanding of topological phases.

Findings

Surface phase transitions with Chern number changes from 1/2 to -3/2 to -1/2.

Sharp jumps in magneto-electric coefficient and quantum Hall conductance.

Phase diagram illustrating Chern number behavior under magnetization.

Abstract

From the low-energy model, the topological field theory indicates that the surface magnetization can open a surface gap in 3D topological insulators (TIs), resulting in a half-quantized Hall conductance. Here by employing the realistic lattice model, we show the occurrence of { the surface phase transitions}, accompanied with the sharp changes of the surface Chern number from $\frac{1}{2}$ to $-\frac{3}{2}$ finally to $-\frac{1}{2}$, in 3D TIs induced by surface magnetization. These surface phase transitions lead to the sudden jumps in the magneto-electric coefficient and the quantum Hall conductance, which are experimentally observable. Furthermore, we present the phase diagram that elucidates the behavior of the 3D TI surface Chern numbers under surface magnetization for different $Z_{4}$ topological numbers. Our study highlights the presence of the new phases with broken bulk-boundary correspondence and enriches understandings of the properties of TIs.