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Main Authors: Lei, Yunlin, Yang, Xinyu, Wang, Shouyu, Zhang, Daliang, Wang, Zitao, Zhang, Jiayou, Yang, Yihao, Wang, Chuanshou, Xiao, Tianqi, Bai, Yinxin, Tian, Junjiang, Chen, Congcong, Han, Yu, Dong, Shuai, Wang, Junling
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.12780
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author Lei, Yunlin
Yang, Xinyu
Wang, Shouyu
Zhang, Daliang
Wang, Zitao
Zhang, Jiayou
Yang, Yihao
Wang, Chuanshou
Xiao, Tianqi
Bai, Yinxin
Tian, Junjiang
Chen, Congcong
Han, Yu
Dong, Shuai
Wang, Junling
author_facet Lei, Yunlin
Yang, Xinyu
Wang, Shouyu
Zhang, Daliang
Wang, Zitao
Zhang, Jiayou
Yang, Yihao
Wang, Chuanshou
Xiao, Tianqi
Bai, Yinxin
Tian, Junjiang
Chen, Congcong
Han, Yu
Dong, Shuai
Wang, Junling
contents Materials possessing long range ordering of magnetic spins or electric dipoles have been the focus of condensed matter research. Among them, ferri-systems with two sublattices of unequal/noncollinear spins or electric dipoles are expected to combine the properties of ferro- and antiferro-systems, but lack experimental observations in single phase materials. This is particularly true for the ferrielectric system, since the electric dipoles usually can be redefined to incorporate the two sublattices into one, making it indistinguishable from ferroelectric. This raises doubts about whether or not ferrielectricity can be considered as an independent ferroic order. Here we report the observation of true ferrielectric behaviors in a hybrid single crystal (MV)[SbBr5] (MV2+ = N,N'-dimethyl-4,4'-bipyridinium or methylviologen), where the two electric dipole sublattices switch asynchronously, thus cannot be reduced to ferroelectric by redefining the unit cell. Furthermore, the complex dipole configuration imparts circularly polarized light sensitivity to the system. An electric field can modulate the non-collinear dipole sublattices and even induce a transition from ferrielectric to ferroelectric state, thereby tuning the helicity-dependent photocurrent. This study opens a new paradigm for the study of true irreducible ferrielectricity (a new class of polar system) and provides an effective approach to the electric field control of spin-orbit coupling and circular photogalvanic effect.
format Preprint
id arxiv_https___arxiv_org_abs_2506_12780
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Electric Field Control of Spin Orbit Coupling and Circular Photogalvanic Effect in a True Ferrielectric Crystal
Lei, Yunlin
Yang, Xinyu
Wang, Shouyu
Zhang, Daliang
Wang, Zitao
Zhang, Jiayou
Yang, Yihao
Wang, Chuanshou
Xiao, Tianqi
Bai, Yinxin
Tian, Junjiang
Chen, Congcong
Han, Yu
Dong, Shuai
Wang, Junling
Materials Science
Materials possessing long range ordering of magnetic spins or electric dipoles have been the focus of condensed matter research. Among them, ferri-systems with two sublattices of unequal/noncollinear spins or electric dipoles are expected to combine the properties of ferro- and antiferro-systems, but lack experimental observations in single phase materials. This is particularly true for the ferrielectric system, since the electric dipoles usually can be redefined to incorporate the two sublattices into one, making it indistinguishable from ferroelectric. This raises doubts about whether or not ferrielectricity can be considered as an independent ferroic order. Here we report the observation of true ferrielectric behaviors in a hybrid single crystal (MV)[SbBr5] (MV2+ = N,N'-dimethyl-4,4'-bipyridinium or methylviologen), where the two electric dipole sublattices switch asynchronously, thus cannot be reduced to ferroelectric by redefining the unit cell. Furthermore, the complex dipole configuration imparts circularly polarized light sensitivity to the system. An electric field can modulate the non-collinear dipole sublattices and even induce a transition from ferrielectric to ferroelectric state, thereby tuning the helicity-dependent photocurrent. This study opens a new paradigm for the study of true irreducible ferrielectricity (a new class of polar system) and provides an effective approach to the electric field control of spin-orbit coupling and circular photogalvanic effect.
title Electric Field Control of Spin Orbit Coupling and Circular Photogalvanic Effect in a True Ferrielectric Crystal
topic Materials Science
url https://arxiv.org/abs/2506.12780