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Main Authors: Kollwitz, Leo, Goerzen, Moritz A., Beyer, Bjarne, Schrautzer, Hendrik, Heinze, Stefan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.12829
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author Kollwitz, Leo
Goerzen, Moritz A.
Beyer, Bjarne
Schrautzer, Hendrik
Heinze, Stefan
author_facet Kollwitz, Leo
Goerzen, Moritz A.
Beyer, Bjarne
Schrautzer, Hendrik
Heinze, Stefan
contents The triple-Q state arises due to the superposition of three symmetry equivalent spin spirals stabilized by higher-order exchange interactions. It has been predicted more than 20 years ago but was only recently discovered in a Mn monolayer on the Re(0001) surface. To date little is known about the thermodynamic properties of this intriguing non-coplanar spin state. Here, we reveal a low-temperature phase transition between the triple-Q and the row-wise antiferromagnetic state in this system via Monte Carlo simulations based on an atomistic spin model parametrized by density functional theory. By modeling the free energy landscape in terms of thermal excitations we derive an analytical expression of the partition function, which allows us to prove that the phase transition is driven by entropy. The predicted phase transition is not unique to Mn/Re(0001) but appears for a wide range of magnetic interaction parameters and is expected to occur also for other multi-Q states.
format Preprint
id arxiv_https___arxiv_org_abs_2508_12829
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Entropy-driven phase transition in a non-collinear antiferromagnet due to higher-order exchange interactions
Kollwitz, Leo
Goerzen, Moritz A.
Beyer, Bjarne
Schrautzer, Hendrik
Heinze, Stefan
Materials Science
The triple-Q state arises due to the superposition of three symmetry equivalent spin spirals stabilized by higher-order exchange interactions. It has been predicted more than 20 years ago but was only recently discovered in a Mn monolayer on the Re(0001) surface. To date little is known about the thermodynamic properties of this intriguing non-coplanar spin state. Here, we reveal a low-temperature phase transition between the triple-Q and the row-wise antiferromagnetic state in this system via Monte Carlo simulations based on an atomistic spin model parametrized by density functional theory. By modeling the free energy landscape in terms of thermal excitations we derive an analytical expression of the partition function, which allows us to prove that the phase transition is driven by entropy. The predicted phase transition is not unique to Mn/Re(0001) but appears for a wide range of magnetic interaction parameters and is expected to occur also for other multi-Q states.
title Entropy-driven phase transition in a non-collinear antiferromagnet due to higher-order exchange interactions
topic Materials Science
url https://arxiv.org/abs/2508.12829