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Main Authors: Luo, Wei, Deng, Sihan, Xie, Muting, Ji, Junyi, Xiang, Hongjun, Bellaiche, Laurent
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.08897
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author Luo, Wei
Deng, Sihan
Xie, Muting
Ji, Junyi
Xiang, Hongjun
Bellaiche, Laurent
author_facet Luo, Wei
Deng, Sihan
Xie, Muting
Ji, Junyi
Xiang, Hongjun
Bellaiche, Laurent
contents Ferroelectricity is a cornerstone of functional materials research, enabling diverse technologies from non-volatile memory to optoelectronics. Recently, type-I integer quantum ferroelectricity (IQFE), unconstrained by symmetry, has been proposed and experimentally demonstrated; however, as it arises from ionic displacements of an integer lattice vector, the initial and final states are macroscopically indistinguishable, rendering the physical properties unchanged. Here, we propose for the first time the nontrivial counterpart (i.e., type-II IQFE) where the polarization difference between the initial and final states is quantized but the macroscopical properties differ. We further demonstrate the existence of type-II IQFE in bulk chiral tellurium. In few-layer tellurium, the total polarization remains nearly quantized, composed of a bulk-inherited quantum component and a small surface-induced contribution. Molecular dynamics simulations reveal surface-initiated, layer-by-layer switching driven by reduced energy barriers, explaining why ferroelectricity was observed experimentally in few-layer tellurium, but not in bulk tellurium yet. Interestingly, the chirality of the initial and final states in bulk tellurium is opposite, suggesting a novel way to control structural chirality with electric field in chiral photonics and nonvolatile ferroelectric memory devices.
format Preprint
id arxiv_https___arxiv_org_abs_2510_08897
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Hidden integer quantum ferroelectricity in chiral Tellurium
Luo, Wei
Deng, Sihan
Xie, Muting
Ji, Junyi
Xiang, Hongjun
Bellaiche, Laurent
Materials Science
Ferroelectricity is a cornerstone of functional materials research, enabling diverse technologies from non-volatile memory to optoelectronics. Recently, type-I integer quantum ferroelectricity (IQFE), unconstrained by symmetry, has been proposed and experimentally demonstrated; however, as it arises from ionic displacements of an integer lattice vector, the initial and final states are macroscopically indistinguishable, rendering the physical properties unchanged. Here, we propose for the first time the nontrivial counterpart (i.e., type-II IQFE) where the polarization difference between the initial and final states is quantized but the macroscopical properties differ. We further demonstrate the existence of type-II IQFE in bulk chiral tellurium. In few-layer tellurium, the total polarization remains nearly quantized, composed of a bulk-inherited quantum component and a small surface-induced contribution. Molecular dynamics simulations reveal surface-initiated, layer-by-layer switching driven by reduced energy barriers, explaining why ferroelectricity was observed experimentally in few-layer tellurium, but not in bulk tellurium yet. Interestingly, the chirality of the initial and final states in bulk tellurium is opposite, suggesting a novel way to control structural chirality with electric field in chiral photonics and nonvolatile ferroelectric memory devices.
title Hidden integer quantum ferroelectricity in chiral Tellurium
topic Materials Science
url https://arxiv.org/abs/2510.08897