欧拉-伯努利纳米梁在温克勒-帕斯捷尔纳克弹性地基上的水磁振动的切比雪夫-里兹法和纳维叶法

Subrat Kumar Jena, S. Pradyumna, S. Chakraverty, Mohamed A. Eltaher
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摘要

本研究采用 Chebyshev-Ritz 方法和 Navier 方法研究了纳米梁在纵向磁场和线性吸湿环境下的振动特性。纳米梁以温克勒-帕斯捷尔纳克弹性基础为特征,并遵循非局部欧拉-伯努利梁理论。利用汉密尔顿原理推导了支配运动方程,并计算了简支-简支(SS)、夹紧-夹紧(CC)和无夹紧(CF)边界条件下的非尺寸频率参数。这项研究的动机是为理解纳米梁在复杂环境中的动态行为提供一个全面、高效的分析框架。通过研究磁性和吸湿性因素对纳米梁振动特性的影响,本研究旨在为纳米结构的设计和优化提供有价值的见解。在切比雪夫-里兹方法中采用移位切比雪夫多项式作为形状函数,为所提出的模型提供了几个优势。首先,这些多项式具有正交特性,可显著提高计算效率。与非正交基函数相比,移位切比雪夫多项式的正交性使数值计算更简单、更流畅。此外,正交性还能确保所得到的方程系统具有良好的条件,即使对于高阶多项式近似也是如此。通过纳维法,可以得到 SS 边界条件的闭式解。通过收敛分析,验证了所提模型与现有模型相比的准确性和有效性。使用纳维法和切比雪夫-里兹法获得的非尺寸频率参数显示出很强的一致性,进一步验证了所提出的纳米梁模型。此外,一项全面的参数研究评估了各种特性的影响,包括小尺度参数、温克勒模量、剪切模量、磁参数和吸湿参数。研究结果有助于深入理解纳米梁在磁场和吸湿环境影响下的振动,为实际应用中纳米结构的设计和优化提供了宝贵的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Chebyshev–Ritz and Navier's methods for hygro‐magneto vibration of Euler–Bernoulli nanobeam resting on Winkler–Pasternak elastic foundation
This research employs Chebyshev–Ritz method along with Navier's method to investigate the vibration characteristics of a nanobeam subject to a longitudinal magnetic field and linear hygroscopic environment. The nanobeam is characterized by a Winkler–Pasternak elastic foundation and follows the nonlocal Euler–Bernoulli beam theory. The governing equation of motion is derived using Hamilton's principle, and non‐dimensional frequency parameters are computed for Simply Supported‐Simply Supported (SS), Clamped‐Clamped (CC), and Clamped‐Free (CF) boundary conditions. The motivation behind this study is to provide a comprehensive and efficient analytical framework for understanding the dynamic behavior of nanobeams in complex environments. By investigating the influence of magnetic and hygroscopic factors on the vibration characteristics of nanobeams, this research aims to offer valuable insights for the design and optimization of nanoscale structures. Employing shifted Chebyshev polynomials as shape functions in Chebyshev–Ritz method offers several advantages in the proposed model. Firstly, these polynomials possess orthogonal properties, which can significantly enhance computational efficiency. The orthogonality of shifted Chebyshev polynomials allow for simpler and more streamlined numerical computations compared to non‐orthogonal basis functions. Additionally, the orthogonality ensures that the resulting system of equations is well‐conditioned, even for higher‐order polynomial approximations. A closed‐form solution for SS boundary condition is obtained through Navier's method. Convergence analysis is performed to validate the accuracy and effectiveness of the proposed model against existing models. The non‐dimensional frequency parameters obtained using both Navier's method and Chebyshev–Ritz method demonstrate strong agreement, further validating the proposed nanobeam model. Additionally, a comprehensive parametric study evaluates the impact of various characteristics, including the small‐scale parameter, Winkler modulus, shear modulus, magnetic parameter, and hygroscopic parameter. The findings contribute to a nuanced understanding of nanobeam vibrations under the influence of a magnetic field and hygroscopic environment, providing valuable insights for the design and optimization of nanoscale structures in practical applications.
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