Noncollinear ferrielectricity in a van der Waals crystal

Jierui Fu; Gang Wang; Yingpeng Qi; Wen He; Yuqiang Fang; Gang Tang; Yanting Peng; Dong Wang; Zhenjie Guan; Xuzhou Sun; Shuming Zhang; Zunyi Deng; Yue Liu; Jiapeng Wang; Songge Li; Tingting Li; Jinjing Zhou; Yuchen Shang; Yankun Yin; Zhaoju Yang; Jinzhong Wang; Yang Ding; Dao Xiang; Liang Zhen; Jiawang Hong; Fuqiang Huang; Junhao Lin; Chengyan Xu; Yang Li

doi:10.1038/s41467-026-70975-2

Noncollinear ferrielectricity in a van der Waals crystal

Jierui Fu
, Gang Wang
, Yingpeng Qi
, Wen He
, Yuqiang Fang^*
, Gang Tang
, Yanting Peng
, Dong Wang
, Zhenjie Guan
, Xuzhou Sun
, Shuming Zhang
, Zunyi Deng
, Yue Liu
, Jiapeng Wang
, Songge Li
, Tingting Li
, Jinjing Zhou
, Yuchen Shang
, Yankun Yin
, Zhaoju Yang

Jinzhong Wang, Yang Ding, Dao Xiang, Liang Zhen, Jiawang Hong^*, Fuqiang Huang^*, Junhao Lin^*, Chengyan Xu^*, Yang Li^*

^*Corresponding author for this work

School of Materials Science and Engineering

Harbin Institute of Technology
Harbin Institute of Technology
Southern University of Science and Technology
University of Science and Technology of China
Shanghai Jiao Tong University
Beijing Institute of Technology
Center for High Pressure Science & Technology Advanced Research
Zhejiang University
College of Physics
Quantum Science Center of Guangdong-Hong Kong-Macao Greater Bay Area (Guangdong)
Harbin Institute of Technology (Shenzhen)

Research output: Contribution to journal › Article › peer-review

Abstract

Inspired by noncollinear magnetic dipole order, noncollinear electric dipole order is anticipated to open up rich ferroelectric physics and new opportunities for device applications. However, establishing such order in single crystals remains challenging, as electric polarization is typically locked to crystallographic axes. Here we report noncollinear ferrielectricity in the van der Waals crystal WO₂Br₂, arising from competition between ferroelectric and antiferroelectric phonon modes. The noncollinear dipole order of WO₂Br₂ is revealed by decoupling the antipolar and the polar displacement components, both of which are directly visualized by scanning transmission electron microscopy. This noncollinear dipole order enables 90° polarization flip under hydrostatic pressure through two energetically degenerate transition pathways. Moreover, ultrafast electron diffraction measurements show that optical excitation drives two distinct coherent phonon modes associated with the ferroelectric and antiferroelectric orders. This work enriches the physics of noncollinear electric dipole order for emergent ferroelectric device applications.

Original language	English
Article number	4245
Journal	Nature Communications
Volume	17
Issue number	1
DOIs	https://doi.org/10.1038/s41467-026-70975-2
State	Published - Dec 2026

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title = "Noncollinear ferrielectricity in a van der Waals crystal",

abstract = "Inspired by noncollinear magnetic dipole order, noncollinear electric dipole order is anticipated to open up rich ferroelectric physics and new opportunities for device applications. However, establishing such order in single crystals remains challenging, as electric polarization is typically locked to crystallographic axes. Here we report noncollinear ferrielectricity in the van der Waals crystal WO2Br2, arising from competition between ferroelectric and antiferroelectric phonon modes. The noncollinear dipole order of WO2Br2 is revealed by decoupling the antipolar and the polar displacement components, both of which are directly visualized by scanning transmission electron microscopy. This noncollinear dipole order enables 90° polarization flip under hydrostatic pressure through two energetically degenerate transition pathways. Moreover, ultrafast electron diffraction measurements show that optical excitation drives two distinct coherent phonon modes associated with the ferroelectric and antiferroelectric orders. This work enriches the physics of noncollinear electric dipole order for emergent ferroelectric device applications.",

author = "Jierui Fu and Gang Wang and Yingpeng Qi and Wen He and Yuqiang Fang and Gang Tang and Yanting Peng and Dong Wang and Zhenjie Guan and Xuzhou Sun and Shuming Zhang and Zunyi Deng and Yue Liu and Jiapeng Wang and Songge Li and Tingting Li and Jinjing Zhou and Yuchen Shang and Yankun Yin and Zhaoju Yang and Jinzhong Wang and Yang Ding and Dao Xiang and Liang Zhen and Jiawang Hong and Fuqiang Huang and Junhao Lin and Chengyan Xu and Yang Li",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = dec,

doi = "10.1038/s41467-026-70975-2",

language = "英语",

volume = "17",

journal = "Nature Communications",

issn = "2041-1723",

publisher = "Nature Research",

number = "1",

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Fu, J, Wang, G, Qi, Y, He, W, Fang, Y, Tang, G, Peng, Y, Wang, D, Guan, Z, Sun, X, Zhang, S, Deng, Z, Liu, Y, Wang, J, Li, S, Li, T, Zhou, J, Shang, Y, Yin, Y, Yang, Z, Wang, J, Ding, Y, Xiang, D, Zhen, L, Hong, J, Huang, F, Lin, J, Xu, C & Li, Y 2026, 'Noncollinear ferrielectricity in a van der Waals crystal', Nature Communications, vol. 17, no. 1, 4245. https://doi.org/10.1038/s41467-026-70975-2

TY - JOUR

T1 - Noncollinear ferrielectricity in a van der Waals crystal

AU - Fu, Jierui

AU - Wang, Gang

AU - Qi, Yingpeng

AU - He, Wen

AU - Fang, Yuqiang

AU - Tang, Gang

AU - Peng, Yanting

AU - Wang, Dong

AU - Guan, Zhenjie

AU - Sun, Xuzhou

AU - Zhang, Shuming

AU - Deng, Zunyi

AU - Liu, Yue

AU - Wang, Jiapeng

AU - Li, Songge

AU - Li, Tingting

AU - Zhou, Jinjing

AU - Shang, Yuchen

AU - Yin, Yankun

AU - Yang, Zhaoju

AU - Wang, Jinzhong

AU - Ding, Yang

AU - Xiang, Dao

AU - Zhen, Liang

AU - Hong, Jiawang

AU - Huang, Fuqiang

AU - Lin, Junhao

AU - Xu, Chengyan

AU - Li, Yang

PY - 2026/12

Y1 - 2026/12

N2 - Inspired by noncollinear magnetic dipole order, noncollinear electric dipole order is anticipated to open up rich ferroelectric physics and new opportunities for device applications. However, establishing such order in single crystals remains challenging, as electric polarization is typically locked to crystallographic axes. Here we report noncollinear ferrielectricity in the van der Waals crystal WO2Br2, arising from competition between ferroelectric and antiferroelectric phonon modes. The noncollinear dipole order of WO2Br2 is revealed by decoupling the antipolar and the polar displacement components, both of which are directly visualized by scanning transmission electron microscopy. This noncollinear dipole order enables 90° polarization flip under hydrostatic pressure through two energetically degenerate transition pathways. Moreover, ultrafast electron diffraction measurements show that optical excitation drives two distinct coherent phonon modes associated with the ferroelectric and antiferroelectric orders. This work enriches the physics of noncollinear electric dipole order for emergent ferroelectric device applications.

AB - Inspired by noncollinear magnetic dipole order, noncollinear electric dipole order is anticipated to open up rich ferroelectric physics and new opportunities for device applications. However, establishing such order in single crystals remains challenging, as electric polarization is typically locked to crystallographic axes. Here we report noncollinear ferrielectricity in the van der Waals crystal WO2Br2, arising from competition between ferroelectric and antiferroelectric phonon modes. The noncollinear dipole order of WO2Br2 is revealed by decoupling the antipolar and the polar displacement components, both of which are directly visualized by scanning transmission electron microscopy. This noncollinear dipole order enables 90° polarization flip under hydrostatic pressure through two energetically degenerate transition pathways. Moreover, ultrafast electron diffraction measurements show that optical excitation drives two distinct coherent phonon modes associated with the ferroelectric and antiferroelectric orders. This work enriches the physics of noncollinear electric dipole order for emergent ferroelectric device applications.

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U2 - 10.1038/s41467-026-70975-2

DO - 10.1038/s41467-026-70975-2

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C2 - 41857059

AN - SCOPUS:105038587661

SN - 2041-1723

VL - 17

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 4245

ER -

Noncollinear ferrielectricity in a van der Waals crystal

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