Microstructural model of a ferroelectrоelastic material taking into account the evolution of defects

For the description of the hysteresis behavior of ferroelectrics/ferroelastics under complex multiaxial combined electrical and/or mechanical loading, a thermodynamically consistent microstructural model of a ferroelectroelastic material is proposed taking into account the presence and evolution of...

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Main Author: Semenov Artem
Format: Article
Language:English
Published: Peter the Great St.Petersburg Polytechnic University 2021-03-01
Series:St. Petersburg Polytechnical University Journal: Physics and Mathematics
Subjects:
Online Access:https://physmath.spbstu.ru/article/2021.51.03/
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spelling doaj-a437bbaead98411a93eb811899c9b4422021-08-30T09:14:55ZengPeter the Great St.Petersburg Polytechnic UniversitySt. Petersburg Polytechnical University Journal: Physics and Mathematics2405-72232021-03-0114110.18721/JPM.1410320714726Microstructural model of a ferroelectrоelastic material taking into account the evolution of defectsSemenov Artem0https://orcid.org/0000-0002-8225-3487Peter the Great St. Petersburg Polytechnic UniversityFor the description of the hysteresis behavior of ferroelectrics/ferroelastics under complex multiaxial combined electrical and/or mechanical loading, a thermodynamically consistent microstructural model of a ferroelectroelastic material is proposed taking into account the presence and evolution of polar point defects. The model also takes into account multiphase composition (tetragonal, rhombohedral and orthorhombic phases and their mixtures), anisotropy of properties, domain structure, and dissipative motion of domain walls. The linear theory of the evolution of charged point defects is proposed based on the free energy of defects in the form of a quadratic form of the polarization vector and strain tensor of defects. The evolution equations of which are obtained on the base of the dissipation inequality. The cases of changing and unchanging (frozen) defects are considered. Their influence on switching processes is investigated. The dependence of the hysteresis loop shift (due intern bias field) on the parameters of the free energy of defects is shown. The mutual influence of crystallites in a polycrystal is taken into account by using the method of two-level finite element homogenization. Comparison of the computation results with experimental curves of dielectric, mechanical, and electromechanical hysteresis for polycrystalline piezoelectric PZT PIC-151, polycrystalline BaTiO3, single-crystal PMN-PZT and KTS doped with acceptor additives, showed a showed good agreement.https://physmath.spbstu.ru/article/2021.51.03/polycrystalline piezoceramicspoint defectconstitutive equationhysteresisfinite element homogenization
collection DOAJ
language English
format Article
sources DOAJ
author Semenov Artem
spellingShingle Semenov Artem
Microstructural model of a ferroelectrоelastic material taking into account the evolution of defects
St. Petersburg Polytechnical University Journal: Physics and Mathematics
polycrystalline piezoceramics
point defect
constitutive equation
hysteresis
finite element homogenization
author_facet Semenov Artem
author_sort Semenov Artem
title Microstructural model of a ferroelectrоelastic material taking into account the evolution of defects
title_short Microstructural model of a ferroelectrоelastic material taking into account the evolution of defects
title_full Microstructural model of a ferroelectrоelastic material taking into account the evolution of defects
title_fullStr Microstructural model of a ferroelectrоelastic material taking into account the evolution of defects
title_full_unstemmed Microstructural model of a ferroelectrоelastic material taking into account the evolution of defects
title_sort microstructural model of a ferroelectrоelastic material taking into account the evolution of defects
publisher Peter the Great St.Petersburg Polytechnic University
series St. Petersburg Polytechnical University Journal: Physics and Mathematics
issn 2405-7223
publishDate 2021-03-01
description For the description of the hysteresis behavior of ferroelectrics/ferroelastics under complex multiaxial combined electrical and/or mechanical loading, a thermodynamically consistent microstructural model of a ferroelectroelastic material is proposed taking into account the presence and evolution of polar point defects. The model also takes into account multiphase composition (tetragonal, rhombohedral and orthorhombic phases and their mixtures), anisotropy of properties, domain structure, and dissipative motion of domain walls. The linear theory of the evolution of charged point defects is proposed based on the free energy of defects in the form of a quadratic form of the polarization vector and strain tensor of defects. The evolution equations of which are obtained on the base of the dissipation inequality. The cases of changing and unchanging (frozen) defects are considered. Their influence on switching processes is investigated. The dependence of the hysteresis loop shift (due intern bias field) on the parameters of the free energy of defects is shown. The mutual influence of crystallites in a polycrystal is taken into account by using the method of two-level finite element homogenization. Comparison of the computation results with experimental curves of dielectric, mechanical, and electromechanical hysteresis for polycrystalline piezoelectric PZT PIC-151, polycrystalline BaTiO3, single-crystal PMN-PZT and KTS doped with acceptor additives, showed a showed good agreement.
topic polycrystalline piezoceramics
point defect
constitutive equation
hysteresis
finite element homogenization
url https://physmath.spbstu.ru/article/2021.51.03/
work_keys_str_mv AT semenovartem microstructuralmodelofaferroelectroelasticmaterialtakingintoaccounttheevolutionofdefects
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