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2017 | OriginalPaper | Buchkapitel

Mathematical Models and Finite Element Approaches for Nanosized Piezoelectric Bodies with Uncoulped and Coupled Surface Effects

verfasst von : Victor A. Eremeyev, A. V. Nasedkin

Erschienen in: Wave Dynamics and Composite Mechanics for Microstructured Materials and Metamaterials

Verlag: Springer Singapore

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Abstract

In this chapter the dynamic problems for piezoelectric nanosized bodies with account for coupled damping and surface effects are considered. For these problems we propose new mathematical model which generalizes the models of the elastic medium with damping in sense of the Rayleigh approach and with surface effects for the cases of piezoelectric materials. Our model of attenuation and surface effects has coupling properties between mechanical and electric fields, both for the damping terms and constitutive equations for piezoelectric materials on the surface. For solving the problems stated the finite element approximations are discussed. A set of effective finite element schemes is examined for finding numerical solutions of week statements for nonstationary problems, steady-state oscillation problems, modal problems and static problems within the framework of modelling of piezoelectric nanosized materials with damping and surface effects. For transient and harmonic problems, we demonstrate that the proposed models allow the use of the mode superposition method. In addition, we note that for transient and static problems we can use efficient finite element algorithms for solving the systems of linear algebraic equations with symmetric quasi-definite matrices both in the case of uncoupled surface effects and in the case of coupled surface effects.

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Titel: Mathematical Models and Finite Element Approaches for Nanosized Piezoelectric Bodies with Uncoulped and Coupled Surface Effects
verfasst von: Victor A. Eremeyev
A. V. Nasedkin
Verlag: Springer Singapore
Buch: Wave Dynamics and Composite Mechanics for Microstructured Materials and Metamaterials
Print ISBN: 978-981-10-3796-2

Electronic ISBN: 978-981-10-3797-9

Copyright-Jahr: 2017
DOI: https://doi.org/10.1007/978-981-10-3797-9_1

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