Magnetoelectric coupling at the domain level in polycrystalline ErMnO3

We explore the impact of a magnetic field on the ferroelectric domain pattern in polycrystalline hexagonal ErMnO3 at cryogenic temperatures. Utilizing piezoelectric force microscopy measurements at 1.65 K, we observe modifications of the topologically protected ferroelectric domain structure induced...

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Veröffentlicht in:	arXiv.org 2024-03
Hauptverfasser:	Schultheiß, J, Puntigam, L, Winkler, M, Krohns, S, Meier, D, Das, H, Evans, D M, Kézsmárki, I
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Schlagworte:	Coupling Cryogenic temperature Ferroelectric domains Ferroelectric materials Ferroelectricity Magnetic domains Magnetic fields Magnetic properties Piezoelectricity Polycrystals
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description	We explore the impact of a magnetic field on the ferroelectric domain pattern in polycrystalline hexagonal ErMnO3 at cryogenic temperatures. Utilizing piezoelectric force microscopy measurements at 1.65 K, we observe modifications of the topologically protected ferroelectric domain structure induced by the magnetic field. These alterations likely result from strain induced by the magnetic field, facilitated by intergranular coupling in polycrystalline multiferroics. Our findings give insights into the interplay between electric and magnetic properties at the local scale and represent a so far unexplored pathway for manipulating topologically protected ferroelectric vortex patterns in hexagonal manganites.
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subjects	Coupling Cryogenic temperature Ferroelectric domains Ferroelectric materials Ferroelectricity Magnetic domains Magnetic fields Magnetic properties Piezoelectricity Polycrystals
title	Magnetoelectric coupling at the domain level in polycrystalline ErMnO3
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