The Mindlin-Medick Plate Theory and Its Application Under Flexoelectricity and Temperature Effects

Q4 Mathematics

应用数学和力学 Pub Date : 2023-01-01 DOI:10.21656/1000-0887.440017

LU Shuang, LI Dongbo, CHEN Jingbo, XI Bo

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引用次数: 0

Abstract

Based on the Hamiltonian variational principle, the 2D field equations and boundary conditions for flexoelectricity were derived, and the corresponding governing equations were obtained through substitution of the constitutive relation and geometric equations into the field equation. The in-plane tensile deformation, thickness-stretch deformation, symmetric thickness-shear deformation, and their coupled flexoelectric polarization of flexoelectric nanoplates caused by inhomogeneous temperature changes, were studied. The displacement fields and electric potential fields were solved with the double Fourier series method. The results demonstrate that, all fields are sensitive to the temperature load, which raises the prospect of controlling the mechanical and electrical behaviors of flexoelectric nanoplates by means of the temperature field. The effects of the thermal field and mechanical field on the displacement field were compared and examined. The work extends the Mindlin-Medick plate structure analysis theory in view of the flexoelectric and temperature effects, and provides a reference for the structural design of micro- and nano-scale devices.

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挠性电和温度效应下的Mindlin-Medick板理论及其应用

基于哈密顿变分原理，推导了柔性电的二维场方程和边界条件，并将本构关系和几何方程代入场方程，得到了相应的控制方程。研究了挠曲电纳米板在非均匀温度变化下的面内拉伸变形、厚度-拉伸变形、对称厚度-剪切变形及其耦合挠曲电极化。用双傅立叶级数法求解了位移场和电位场。结果表明，所有场对温度载荷都很敏感，这为利用温度场控制柔性电纳米板的力学和电学行为提供了前景。对比分析了热场和力学场对位移场的影响。本研究对Mindlin-Medick板结构分析理论进行了扩展，考虑了挠曲电效应和温度效应，为微纳米器件的结构设计提供了参考。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

应用数学和力学 Mathematics-Applied Mathematics

CiteScore

1.20

自引率

0.00%

发文量

6042

期刊介绍： Applied Mathematics and Mechanics was founded in 1980 by CHIEN Wei-zang, a celebrated Chinese scientist in mechanics and mathematics. The current editor in chief is Professor LU Tianjian from Nanjing University of Aeronautics and Astronautics. The Journal was a quarterly in the beginning, a bimonthly the next year, and then a monthly ever since 1985. It carries original research papers on mechanics, mathematical methods in mechanics and interdisciplinary mechanics based on artificial intelligence mathematics. It also strengthens attention to mechanical issues in interdisciplinary fields such as mechanics and information networks, system control, life sciences, ecological sciences, new energy, and new materials, making due contributions to promoting the development of new productive forces.