Emergent Momentum-Space Skyrmion Texture on the Surface of Topological Insulators

TL;DR

This paper predicts a transition from hedgehog to skyrmion spin textures in the momentum space of topological insulator surfaces under an exchange field, revealing a topological phase change without energy gap closing.

Contribution

It introduces a novel momentum-space skyrmion texture emerging on the surface of topological insulators under magnetic influence, expanding understanding of topological phase transitions.

Findings

Skyrmion texture appears beyond a critical exchange field.

Topological phase transition occurs without energy gap closing.

Quantized Hall conductance remains unchanged during transition.

Abstract

The quantum anomalous Hall effect has been theoretically predicted and experimentally verified in magnetic topological insulators. In addition, the surface states of these materials exhibit a hedgehog-like "spin" texture in momentum space. Here, we apply the previously formulated low-energy model for Bi$_2$Se$_3$, a parent compound for magnetic topological insulators, to a slab geometry in which an exchange field acts only within one of the surface layers. In this sample set up, the hedgehog transforms into a skyrmion texture beyond a critical exchange field. This critical field marks a transition between two topologically distinct phases. The topological phase transition takes place without energy gap closing at the Fermi level and leaves the transverse Hall conductance unchanged and quantized to $e^2/2h$. The momentum-space skyrmion texture persists in a finite field range. It may find its realization in hybrid heterostructures with an interface between a three-dimensional topological insulator and a ferromagnetic insulator.