Dynamics and formation of antiferromagnetic textures in MnBi$_2$Te$_4$ single crystal

TL;DR

This study uses coherent X-ray imaging to visualize antiferromagnetic domains and domain walls in MnBi$_2$Te$_4$, revealing complex hysteresis behavior and domain dynamics crucial for understanding its magnetic properties.

Contribution

First direct visualization of AFM domain morphology and wall dynamics in MnBi$_2$Te$_4$ using coherent X-ray imaging, highlighting hysteresis and energy landscape complexities.

Findings

Domain walls are approximately 550 nm wide.

AFM order parameter follows neutron scattering data.

Pronounced hysteresis in domain evolution around T_N.

Abstract

We report coherent X-ray imaging of antiferromagnetic (AFM) domains and domain walls in MnBi$_2$Te$_4$, an intrinsic AFM topological insulator. This technique enables direct visualization of domain morphology without reconstruction algorithms, allowing us to resolve antiphase domain walls as distinct dark lines arising from the A-type AFM structure. The wall width is determined to be 550(30) nm, in good agreement with earlier magnetic force microscopy results. The temperature dependence of the AFM order parameter extracted from our images closely follows previous neutron scattering data. Remarkably, however, we find a pronounced hysteresis in the evolution of domains and domain walls: upon cooling, dynamic reorganizations occur within a narrow $\sim$1 K interval below $T_N$, whereas upon warming, the domain configuration remains largely unchanged until AFM order disappears. These findings reveal a complex energy landscape in MnBi$_2$Te$_4$, governed by the interplay of exchange, anisotropy, and domain-wall energies, and underscore the critical role of AFM domain-wall dynamics in shaping its physical properties.