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Main Authors: Wen, Weiru, Zeng, Fan-Da, Xu, Ben, Ke, Bi, Xing, Zhipeng, Thong, Hao-Cheng, Wang, Ke
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.05245
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author Wen, Weiru
Zeng, Fan-Da
Xu, Ben
Ke, Bi
Xing, Zhipeng
Thong, Hao-Cheng
Wang, Ke
author_facet Wen, Weiru
Zeng, Fan-Da
Xu, Ben
Ke, Bi
Xing, Zhipeng
Thong, Hao-Cheng
Wang, Ke
contents Atomistic control of phase boundaries is crucial for optimizing the functional properties of solid-solution ferroelectrics, yet their microstructural mechanisms remain elusive. Here, we harness machine-learning-driven molecular dynamics to resolve the phase boundary behavior in the KNbO3-KTaO3 (KNTO) system. Our simulations reveal that chemical composition and ordering enable precise modulation of polymorphic phase boundaries (PPBs), offering a versatile pathway for materials engineering. Diffused PPBs and polar nano regions, predicted by our model, highly match with experiments, underscoring the fidelity of the machine-learning atomistic simulation. Crucially, we identify elastic and electrostatic mismatches between ferroelectric KNbO3 and paraelectric KTaO3 as the driving forces behind complex microstructural evolution. This work not only resolves the longstanding microstructural debate but also establishes a generalizable framework for phase boundary engineering toward next-generation high-performance ferroelectrics.
format Preprint
id arxiv_https___arxiv_org_abs_2505_05245
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine learning-enabled atomistic insights into phase boundary engineering of solid-solution ferroelectrics
Wen, Weiru
Zeng, Fan-Da
Xu, Ben
Ke, Bi
Xing, Zhipeng
Thong, Hao-Cheng
Wang, Ke
Materials Science
Computational Physics
Atomistic control of phase boundaries is crucial for optimizing the functional properties of solid-solution ferroelectrics, yet their microstructural mechanisms remain elusive. Here, we harness machine-learning-driven molecular dynamics to resolve the phase boundary behavior in the KNbO3-KTaO3 (KNTO) system. Our simulations reveal that chemical composition and ordering enable precise modulation of polymorphic phase boundaries (PPBs), offering a versatile pathway for materials engineering. Diffused PPBs and polar nano regions, predicted by our model, highly match with experiments, underscoring the fidelity of the machine-learning atomistic simulation. Crucially, we identify elastic and electrostatic mismatches between ferroelectric KNbO3 and paraelectric KTaO3 as the driving forces behind complex microstructural evolution. This work not only resolves the longstanding microstructural debate but also establishes a generalizable framework for phase boundary engineering toward next-generation high-performance ferroelectrics.
title Machine learning-enabled atomistic insights into phase boundary engineering of solid-solution ferroelectrics
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2505.05245