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Hauptverfasser: Ren, Guodong, Jung, Gwan Yeong, Chen, Huandong, Wang, Chong, Zhao, Boyang, Vasudevan, Rama K., Hachtel, Jordan A., Lupini, Andrew R., Chi, Miaofang, Xiao, Di, Ravichandran, Jayakanth, Mishra, Rohan
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2408.04051
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author Ren, Guodong
Jung, Gwan Yeong
Chen, Huandong
Wang, Chong
Zhao, Boyang
Vasudevan, Rama K.
Hachtel, Jordan A.
Lupini, Andrew R.
Chi, Miaofang
Xiao, Di
Ravichandran, Jayakanth
Mishra, Rohan
author_facet Ren, Guodong
Jung, Gwan Yeong
Chen, Huandong
Wang, Chong
Zhao, Boyang
Vasudevan, Rama K.
Hachtel, Jordan A.
Lupini, Andrew R.
Chi, Miaofang
Xiao, Di
Ravichandran, Jayakanth
Mishra, Rohan
contents Noncollinear ferroic materials are sought after as testbeds to explore the intimate connections between topology and symmetry, which result in electronic, optical and magnetic functionalities not observed in collinear ferroic materials. For example, ferroaxial materials have ordered rotational structural distortions that break mirror symmetry and induce chirality. When ferroaxial order is coupled with ferroelectricity arising from a broken inversion symmetry, it offers the prospect of electric-field-control of the ferroaxial distortions and opens up new tunable functionalities. However, chiral multiferroics, especially ones stable at room temperature, are rare. We report the discovery of a strain-stabilized, room-temperature chiral multiferroic phase in single crystals of BaTiS$_3$, a quasi-one-dimensional (1D) hexagonal chalcogenide. Using first-principles calculations, we predict the stabilization of this multiferroic phase having $P6_3$ space group for biaxial tensile strains exceeding 1.5% applied on the basal ab-plane of the room temperature $P6_3cm$ phase of BaTiS$_3$. The chiral multiferroic phase is characterized by rotational distortions of select TiS$_6$ octahedra around the long $c$-axis and polar displacement of Ti atoms along the $c$-axis. We used an innovative approach using focused ion beam milling to make appropriately strained samples of BaTiS$_3$. The ferroaxial and ferroelectric distortions, and their domains in $P6_3$-BaTiS$_3$ were directly resolved using atomic resolution scanning transmission electron microscopy. Landau-based phenomenological modeling predicts a strong coupling between the ferroelectric and the ferroaxial order making $P6_3$-BaTiS$_3$ an attractive test bed for achieving electric-field control of chirality-related phenomena such as circular photo-galvanic current and the Rashba effect.
format Preprint
id arxiv_https___arxiv_org_abs_2408_04051
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Strain-driven stabilization of a room-temperature chiral multiferroic with coupled ferroaxial and ferroelectric order
Ren, Guodong
Jung, Gwan Yeong
Chen, Huandong
Wang, Chong
Zhao, Boyang
Vasudevan, Rama K.
Hachtel, Jordan A.
Lupini, Andrew R.
Chi, Miaofang
Xiao, Di
Ravichandran, Jayakanth
Mishra, Rohan
Materials Science
Mesoscale and Nanoscale Physics
Noncollinear ferroic materials are sought after as testbeds to explore the intimate connections between topology and symmetry, which result in electronic, optical and magnetic functionalities not observed in collinear ferroic materials. For example, ferroaxial materials have ordered rotational structural distortions that break mirror symmetry and induce chirality. When ferroaxial order is coupled with ferroelectricity arising from a broken inversion symmetry, it offers the prospect of electric-field-control of the ferroaxial distortions and opens up new tunable functionalities. However, chiral multiferroics, especially ones stable at room temperature, are rare. We report the discovery of a strain-stabilized, room-temperature chiral multiferroic phase in single crystals of BaTiS$_3$, a quasi-one-dimensional (1D) hexagonal chalcogenide. Using first-principles calculations, we predict the stabilization of this multiferroic phase having $P6_3$ space group for biaxial tensile strains exceeding 1.5% applied on the basal ab-plane of the room temperature $P6_3cm$ phase of BaTiS$_3$. The chiral multiferroic phase is characterized by rotational distortions of select TiS$_6$ octahedra around the long $c$-axis and polar displacement of Ti atoms along the $c$-axis. We used an innovative approach using focused ion beam milling to make appropriately strained samples of BaTiS$_3$. The ferroaxial and ferroelectric distortions, and their domains in $P6_3$-BaTiS$_3$ were directly resolved using atomic resolution scanning transmission electron microscopy. Landau-based phenomenological modeling predicts a strong coupling between the ferroelectric and the ferroaxial order making $P6_3$-BaTiS$_3$ an attractive test bed for achieving electric-field control of chirality-related phenomena such as circular photo-galvanic current and the Rashba effect.
title Strain-driven stabilization of a room-temperature chiral multiferroic with coupled ferroaxial and ferroelectric order
topic Materials Science
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2408.04051