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Autori principali: Zemp, Yannik, Hassanpour, Ehsan, Horstmann, Jan Gerrit, Tokunaga, Yusuke, Taguchi, Yasujiro, Tokura, Yoshinori, Lottermoser, Thomas, Weber, Mads C., Fiebig, Manfred
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2505.16085
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author Zemp, Yannik
Hassanpour, Ehsan
Horstmann, Jan Gerrit
Tokunaga, Yusuke
Taguchi, Yasujiro
Tokura, Yoshinori
Lottermoser, Thomas
Weber, Mads C.
Fiebig, Manfred
author_facet Zemp, Yannik
Hassanpour, Ehsan
Horstmann, Jan Gerrit
Tokunaga, Yusuke
Taguchi, Yasujiro
Tokura, Yoshinori
Lottermoser, Thomas
Weber, Mads C.
Fiebig, Manfred
contents In many multiferroics, rare-earth and transition-metal orders exist side by side. For analyzing their interaction and its consequences for the multiferroic state, the associated domain patterns and their spatial correlation can give valuable insight. Unfortunately, this is often hampered by the lack of access to the domains of the rare-earth order. Here, we uncover such a domain pattern for the antiferromagnetic and multiferroic Dy$_{0.7}$Tb$_{0.3}$FeO$_3$. Optical second harmonic generation reveals the formation of column-like Dy/Tb domains. Interestingly, the columns form perpendicular to the magnetically induced electric polarization. Hence, the antiferromagnetic rare-earth order forces the ferroelectric domains to form nominally charged head-to-head and tail-to-tail domain walls, thus playing a leading role in the domain formation within the multiferroic phase. In turn, to reduce energy cost, the ferroelectric order causes a reduced rare-earth domain-wall density along the direction of the electric polarization. This interplay highlights the multiferroic character of the Dy$_{0.7}$Tb$_{0.3}$FeO$_3$ domain pattern. We position Dy$_{0.7}$Tb$_{0.3}$FeO$_3$ within the broader landscape of rare-earth multiferroics and identify three distinct scenarios for the role of rare-earth order in these.
format Preprint
id arxiv_https___arxiv_org_abs_2505_16085
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Distribution of antiferromagnetic rare-earth domains in multiferroic Dy$_{0.7}$Tb$_{0.3}$FeO$_3$
Zemp, Yannik
Hassanpour, Ehsan
Horstmann, Jan Gerrit
Tokunaga, Yusuke
Taguchi, Yasujiro
Tokura, Yoshinori
Lottermoser, Thomas
Weber, Mads C.
Fiebig, Manfred
Materials Science
In many multiferroics, rare-earth and transition-metal orders exist side by side. For analyzing their interaction and its consequences for the multiferroic state, the associated domain patterns and their spatial correlation can give valuable insight. Unfortunately, this is often hampered by the lack of access to the domains of the rare-earth order. Here, we uncover such a domain pattern for the antiferromagnetic and multiferroic Dy$_{0.7}$Tb$_{0.3}$FeO$_3$. Optical second harmonic generation reveals the formation of column-like Dy/Tb domains. Interestingly, the columns form perpendicular to the magnetically induced electric polarization. Hence, the antiferromagnetic rare-earth order forces the ferroelectric domains to form nominally charged head-to-head and tail-to-tail domain walls, thus playing a leading role in the domain formation within the multiferroic phase. In turn, to reduce energy cost, the ferroelectric order causes a reduced rare-earth domain-wall density along the direction of the electric polarization. This interplay highlights the multiferroic character of the Dy$_{0.7}$Tb$_{0.3}$FeO$_3$ domain pattern. We position Dy$_{0.7}$Tb$_{0.3}$FeO$_3$ within the broader landscape of rare-earth multiferroics and identify three distinct scenarios for the role of rare-earth order in these.
title Distribution of antiferromagnetic rare-earth domains in multiferroic Dy$_{0.7}$Tb$_{0.3}$FeO$_3$
topic Materials Science
url https://arxiv.org/abs/2505.16085