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Main Authors: Luo, Wei, Deng, Shihan, Xiang, Hongjun, Bellaiche, Laurent
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.14328
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author Luo, Wei
Deng, Shihan
Xiang, Hongjun
Bellaiche, Laurent
author_facet Luo, Wei
Deng, Shihan
Xiang, Hongjun
Bellaiche, Laurent
contents Recent theoretical and experimental advances in quantum ferroelectrics suggest that ferroelectricity can also emerge in non-polar space group, highlighting the limitations of conventional polar space group criteria in identifying ferroelectric materials. Here, we introduce a unified definition based on switchable polarization differences between energetically equivalent states, which naturally encompasses conventional and quantum ferroelectrics. Guided by this principle, we implement a high-throughput screening strategy that systematically identifies both conventional and quantum ferroelectrics among experimentally synthesized materials. In particular, we identify a new type of quantum ferroelectric in which the quantized polarization arises from arbitrary ionic displacements, in contrast to previous quantum ferroelectrics (including both fractional and integer quantum ferroelectrics) where quantized polarization results from fractional or integer ionic displacements. Notably, we find that materials such as Ba3I6 and Cs2PdC2 exhibit low switching barriers and robust insulating behavior, highlighting their experimental viability. Our results reconcile conventional and quantum ferroelectrics, expand the accessible materials landscape, and provide a practical roadmap for discovering next-generation ferroelectrics with advanced switchable functionalities.
format Preprint
id arxiv_https___arxiv_org_abs_2605_14328
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Unified definition of ferroelectricity
Luo, Wei
Deng, Shihan
Xiang, Hongjun
Bellaiche, Laurent
Materials Science
Mesoscale and Nanoscale Physics
Computational Physics
Recent theoretical and experimental advances in quantum ferroelectrics suggest that ferroelectricity can also emerge in non-polar space group, highlighting the limitations of conventional polar space group criteria in identifying ferroelectric materials. Here, we introduce a unified definition based on switchable polarization differences between energetically equivalent states, which naturally encompasses conventional and quantum ferroelectrics. Guided by this principle, we implement a high-throughput screening strategy that systematically identifies both conventional and quantum ferroelectrics among experimentally synthesized materials. In particular, we identify a new type of quantum ferroelectric in which the quantized polarization arises from arbitrary ionic displacements, in contrast to previous quantum ferroelectrics (including both fractional and integer quantum ferroelectrics) where quantized polarization results from fractional or integer ionic displacements. Notably, we find that materials such as Ba3I6 and Cs2PdC2 exhibit low switching barriers and robust insulating behavior, highlighting their experimental viability. Our results reconcile conventional and quantum ferroelectrics, expand the accessible materials landscape, and provide a practical roadmap for discovering next-generation ferroelectrics with advanced switchable functionalities.
title Unified definition of ferroelectricity
topic Materials Science
Mesoscale and Nanoscale Physics
Computational Physics
url https://arxiv.org/abs/2605.14328