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Main Authors: Sheng, Yuxuan, Wu, Menghao
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.11409
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author Sheng, Yuxuan
Wu, Menghao
author_facet Sheng, Yuxuan
Wu, Menghao
contents We predict the existence of abnormal volcano-like temperature dependence of polarization or magnetization with maxima located at elevated temperature, distinct from classical model based on Landau theory. One case is ferroelectricity with long ion displacements and quantized polarizations that cannot be used for expansion in Landau model, and the switching pathway involves various metastable phases where the polar phase is higher both in energy and entropy compared with non-polar phase. Another case is compensated antiferromagnets with two opposite spin lattices of different spin exchange constants. Such difference can be utilized for a unique type of temperature differentiated multiferroicity, where large magnetizations can be reversed upon ferroelectric switching between two Curie temperature with alternating half of spins in paramagnetic state. We demonstrate these proposals by first-principles calculations on several paradigmatic systems, including magnetic bilayers intercalated by Ag ions or metal molecules.
format Preprint
id arxiv_https___arxiv_org_abs_2507_11409
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Volcano-Like Ferroic Transitions Deviating from the Model of Landau Theory
Sheng, Yuxuan
Wu, Menghao
Materials Science
Mesoscale and Nanoscale Physics
We predict the existence of abnormal volcano-like temperature dependence of polarization or magnetization with maxima located at elevated temperature, distinct from classical model based on Landau theory. One case is ferroelectricity with long ion displacements and quantized polarizations that cannot be used for expansion in Landau model, and the switching pathway involves various metastable phases where the polar phase is higher both in energy and entropy compared with non-polar phase. Another case is compensated antiferromagnets with two opposite spin lattices of different spin exchange constants. Such difference can be utilized for a unique type of temperature differentiated multiferroicity, where large magnetizations can be reversed upon ferroelectric switching between two Curie temperature with alternating half of spins in paramagnetic state. We demonstrate these proposals by first-principles calculations on several paradigmatic systems, including magnetic bilayers intercalated by Ag ions or metal molecules.
title Volcano-Like Ferroic Transitions Deviating from the Model of Landau Theory
topic Materials Science
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2507.11409