Topological magnetic phase transition in Eu-based A-type antiferromagnets

TL;DR

This paper investigates a topological magnetic phase transition in Eu-based A-type antiferromagnets, providing numerical evidence that a Berezinskii-Kosterlitz-Thouless transition explains the colossal magnetoresistance observed in EuCd₂P₂.

Contribution

The study models EuCd₂P₂'s magnetic phases and demonstrates a vortex-antivortex unbinding transition consistent with experimental CMR behavior.

Findings

Model exhibits vortex-antivortex unbinding phase transition.

Transition sensitivity matches experimental CMR signals.

Numerical evidence links BKT transition to magnetic properties.

Abstract

Recently, a colossal magnetoresistance (CMR) was observed in EuCd$_2$P$_2$ -- a compound that does not fit the conventional mixed-valence paradigm. Instead, experimental evidence points at a resistance driven by strong magnetic fluctuations within the two-dimensional ($2d$) ferromagnetic (FM) planes of the layered antiferromagnetic (AFM) structure. While the experimental results have not yet been fully understood, a recent theory relates the CMR to a topological vortex-antivortex unbinding, i.e., Berezinskii-Kosterlitz-Thouless (BKT), phase transition. Motivated by these observations, in this work we explore the magnetic phases hosted by a microscopic classical magnetic model for EuCd$_2$P$_2$, which easily generalizes to other Eu A-type antiferromagnetic compounds. Using Monte Carlo techniques to probe the specific heat and the helicity modulus, we show that our model can exhibit a vortex-antivortex unbinding phase transition. We find that this phase transition displays the same sensitivity to in-plane magnetization, interlayer coupling, and easy-plane anisotropy that is observed experimentally in the CMR signal, providing qualitative numerical evidence that the effect is related to a magnetic BKT transition.