The Meshless Analysis of Scale-Dependent Problems for Coupled Fields

The Meshless Analysis of Scale-Dependent Problems for Coupled Fields

The meshless local Petrov–Galerkin (MLPG) method was developed to analyze 2D problems for flexoelectricity and higher-grade thermoelectricity. Both problems were multiphysical and scale-dependent. The size effect was considered by the strain and electric field gradients in the flexoelectricity, and...

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Main Authors: Jan Sladek, Vladimir Sladek, Pihua H. Wen
Format: Article
Language:English
Published: MDPI AG 2020-06-01
Series:Materials
Subjects:
MLS approximation
gradients of strains
gradients of electric intensity vector
higher-grade heat flux
Online Access:https://www.mdpi.com/1996-1944/13/11/2527
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spelling doaj-27916b24b94b4c8dbc36c22e85688e3b2020-11-25T03:18:56ZengMDPI AGMaterials1996-19442020-06-01132527252710.3390/ma13112527The Meshless Analysis of Scale-Dependent Problems for Coupled FieldsJan Sladek0Vladimir Sladek1Pihua H. Wen2Institute of Construction and Architecture, Slovak Academy of Sciences, 84503 Bratislava, SlovakiaInstitute of Construction and Architecture, Slovak Academy of Sciences, 84503 Bratislava, SlovakiaSchool of Engineering and Materials Sciences, Queen Mary University of London, Mile End, London E14NS, UKThe meshless local Petrov–Galerkin (MLPG) method was developed to analyze 2D problems for flexoelectricity and higher-grade thermoelectricity. Both problems were multiphysical and scale-dependent. The size effect was considered by the strain and electric field gradients in the flexoelectricity, and higher-grade heat flux in the thermoelectricity. The variational principle was applied to derive the governing equations within the higher-grade theory of considered continuous media. The order of derivatives in the governing equations was higher than in their counterparts in classical theory. In the numerical treatment, the coupled governing partial differential equations (PDE) were satisfied in a local weak-form on small fictitious subdomains with a simple test function. Physical fields were approximated by the moving least-squares (MLS) scheme. Applying the spatial approximations in local integral equations and to boundary conditions, a system of algebraic equations was obtained for the nodal unknowns.https://www.mdpi.com/1996-1944/13/11/2527MLS approximationgradients of strainsgradients of electric intensity vectorhigher-grade heat flux
collection DOAJ
language English
format Article
sources DOAJ
author Jan Sladek
Vladimir Sladek
Pihua H. Wen
spellingShingle Jan Sladek
Vladimir Sladek
Pihua H. Wen
The Meshless Analysis of Scale-Dependent Problems for Coupled Fields
Materials
MLS approximation
gradients of strains
gradients of electric intensity vector
higher-grade heat flux
author_facet Jan Sladek
Vladimir Sladek
Pihua H. Wen
author_sort Jan Sladek
title The Meshless Analysis of Scale-Dependent Problems for Coupled Fields
title_short The Meshless Analysis of Scale-Dependent Problems for Coupled Fields
title_full The Meshless Analysis of Scale-Dependent Problems for Coupled Fields
title_fullStr The Meshless Analysis of Scale-Dependent Problems for Coupled Fields
title_full_unstemmed The Meshless Analysis of Scale-Dependent Problems for Coupled Fields
title_sort meshless analysis of scale-dependent problems for coupled fields
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2020-06-01
description The meshless local Petrov–Galerkin (MLPG) method was developed to analyze 2D problems for flexoelectricity and higher-grade thermoelectricity. Both problems were multiphysical and scale-dependent. The size effect was considered by the strain and electric field gradients in the flexoelectricity, and higher-grade heat flux in the thermoelectricity. The variational principle was applied to derive the governing equations within the higher-grade theory of considered continuous media. The order of derivatives in the governing equations was higher than in their counterparts in classical theory. In the numerical treatment, the coupled governing partial differential equations (PDE) were satisfied in a local weak-form on small fictitious subdomains with a simple test function. Physical fields were approximated by the moving least-squares (MLS) scheme. Applying the spatial approximations in local integral equations and to boundary conditions, a system of algebraic equations was obtained for the nodal unknowns.
topic MLS approximation
gradients of strains
gradients of electric intensity vector
higher-grade heat flux
url https://www.mdpi.com/1996-1944/13/11/2527
work_keys_str_mv AT jansladek themeshlessanalysisofscaledependentproblemsforcoupledfields
AT vladimirsladek themeshlessanalysisofscaledependentproblemsforcoupledfields
AT pihuahwen themeshlessanalysisofscaledependentproblemsforcoupledfields
AT jansladek meshlessanalysisofscaledependentproblemsforcoupledfields
AT vladimirsladek meshlessanalysisofscaledependentproblemsforcoupledfields
AT pihuahwen meshlessanalysisofscaledependentproblemsforcoupledfields
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