Simultaneous effects of material and geometric nonlinearities on nonlinear vibration of nanobeam with surface energy effects

IF 2.7 3区 材料科学 Q2 ENGINEERING, MECHANICAL
Reza Hassannejad, Babak Alizadeh-Hamidi
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Abstract

This study explores the nonlinear free vibration of a nanobeam within the framework of nonlocal elasticity theory. It incorporates the materials nonlinear behavior, von Kármán strains, and surface elasticity theory. The stress–strain relationship in this study includes the quadratic material nonlinearity, which is typically ignored in previous research. The governing equations are derived through the application of Hamiltons principle. Using Galerkins method on the partial differential equations, the nonlinear differential equation governing the system is derived. The cubic nonlinearity in this equation arises from geometrical effects, while the quantic nonlinearity is attributed to material nonlinearity. The derived nonlinear differential equation is addressed utilizing the modified Homotopy Perturbation method. This approach yields the nonlinear time response and nonlinear frequency of the nanobeam, taking into account the effects of material nonlinearity and surface phenomena. The findings demonstrated the combined impact of surface effects and nonlinear material behavior on the nonlinear time response and frequency of the nanobeam. The natural frequency of the nanobeam was analyzed using the Elman neural network. Various inputs were fed into the network, and its output was compared with the exact solution for the natural frequency to assess accuracy. Additionally, the influence of material nonlinearity and surface effects on the phase trajectories of the nanobeam is examined. For validation purposes, the results are compared with those obtained using the fourth-order Runge–Kutta numerical method and previous studies.

Abstract Image

材料和几何非线性对具有表面能效应的纳米梁非线性振动的同时影响
本研究在非局部弹性理论框架内探讨了纳米梁的非线性自由振动。它结合了材料非线性行为、von Kármán应变和表面弹性理论。本研究中的应力-应变关系包括二次材料非线性,这在以往的研究中通常被忽略。通过应用哈密顿原理推导出控制方程。在偏微分方程上使用 Galerkins 方法,得出了系统的非线性微分方程。该方程中的立方非线性来自几何效应,而量子非线性则归因于材料非线性。推导出的非线性微分方程采用修正的同调钝化法进行处理。考虑到材料非线性和表面现象的影响,这种方法得出了纳米梁的非线性时间响应和非线性频率。研究结果表明了表面效应和非线性材料行为对纳米梁非线性时间响应和频率的综合影响。使用 Elman 神经网络分析了纳米梁的固有频率。向该网络输入各种输入,并将其输出与固有频率的精确解进行比较,以评估其准确性。此外,还研究了材料非线性和表面效应对纳米梁相位轨迹的影响。为了进行验证,将结果与使用四阶 Runge-Kutta 数值方法和以前的研究得出的结果进行了比较。
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来源期刊
International Journal of Mechanics and Materials in Design
International Journal of Mechanics and Materials in Design ENGINEERING, MECHANICAL-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
6.00
自引率
5.40%
发文量
41
审稿时长
>12 weeks
期刊介绍: It is the objective of this journal to provide an effective medium for the dissemination of recent advances and original works in mechanics and materials'' engineering and their impact on the design process in an integrated, highly focused and coherent format. The goal is to enable mechanical, aeronautical, civil, automotive, biomedical, chemical and nuclear engineers, researchers and scientists to keep abreast of recent developments and exchange ideas on a number of topics relating to the use of mechanics and materials in design. Analytical synopsis of contents: The following non-exhaustive list is considered to be within the scope of the International Journal of Mechanics and Materials in Design: Intelligent Design: Nano-engineering and Nano-science in Design; Smart Materials and Adaptive Structures in Design; Mechanism(s) Design; Design against Failure; Design for Manufacturing; Design of Ultralight Structures; Design for a Clean Environment; Impact and Crashworthiness; Microelectronic Packaging Systems. Advanced Materials in Design: Newly Engineered Materials; Smart Materials and Adaptive Structures; Micromechanical Modelling of Composites; Damage Characterisation of Advanced/Traditional Materials; Alternative Use of Traditional Materials in Design; Functionally Graded Materials; Failure Analysis: Fatigue and Fracture; Multiscale Modelling Concepts and Methodology; Interfaces, interfacial properties and characterisation. Design Analysis and Optimisation: Shape and Topology Optimisation; Structural Optimisation; Optimisation Algorithms in Design; Nonlinear Mechanics in Design; Novel Numerical Tools in Design; Geometric Modelling and CAD Tools in Design; FEM, BEM and Hybrid Methods; Integrated Computer Aided Design; Computational Failure Analysis; Coupled Thermo-Electro-Mechanical Designs.
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