Vibration Analysis of Single-Walled Carbon Nanotubes Embedded in a Polymer Matrix under Magnetic Field Considering the Surface Effect Based on Nonlocal Strain Gradient Elasticity Theory

IF 1.8 4区材料科学 Q2 MATERIALS SCIENCE, CHARACTERIZATION & TESTING Physical Mesomechanics Pub Date : 2023-06-30 DOI:10.1134/S1029959923030074

N. Moulay, M. Liani, F. Bourada, A. Tounsi, M. H. Ghazwani

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Abstract

Single-walled carbon nanotubes (SWCNTs) in an elastic medium under a longitudinal magnetic field have piqued the interest of researchers as elements utilized in nanoelectro-magneto-mechanical systems (NEMMS). This work presents the vibration analysis of embedded SWCNTs using the nonlocal second-order strain gradient elasticity theory. Considering the surface effect, the characteristic equation of motion for a SWCNT embedded in a polymer matrix under a longitudinal magnetic field is formulated and derived. The dependence of the distinct natural frequency of SWCNTs on the nanotube chiral angle and diameter is clarified. The effects of various parameters on the vibration characteristics of SWCNTs are examined and discussed, including the longitudinal magnetic field, surface effect, chiral index, chiral angle, chirality of SWCNTs, vibrational mode number, aspect ratio (length-to-diameter ratio), nonlocal and material length scale parameters. The numerical findings of this work might be helpful in the study and implementation of embedded SWCNTs as NEMMS devices.

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基于非局部应变梯度弹性理论的单壁碳纳米管嵌入聚合物基体磁场下考虑表面效应的振动分析

纵向磁场下弹性介质中的单壁碳纳米管(SWCNTs)作为纳米电磁机械系统(NEMMS)中的元件引起了研究人员的兴趣。本文采用非局部二阶应变梯度弹性理论对嵌入的SWCNTs进行了振动分析。考虑表面效应，推导了嵌入聚合物基体的单壁碳纳米管在纵向磁场作用下的运动特征方程。澄清了SWCNTs不同固有频率对纳米管手性角和直径的依赖关系。考察并讨论了纵向磁场、表面效应、手性指数、手性角、SWCNTs的手性、振动模态数、长径比(长径比)、非局部尺度和材料长度尺度等参数对SWCNTs振动特性的影响。这项工作的数值结果可能有助于嵌入式SWCNTs作为NEMMS器件的研究和实现。

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来源期刊

Physical Mesomechanics Materials Science-General Materials Science

CiteScore

3.50

自引率

18.80%

发文量

期刊介绍： The journal provides an international medium for the publication of theoretical and experimental studies and reviews related in the physical mesomechanics and also solid-state physics, mechanics, materials science, geodynamics, non-destructive testing and in a large number of other fields where the physical mesomechanics may be used extensively. Papers dealing with the processing, characterization, structure and physical properties and computational aspects of the mesomechanics of heterogeneous media, fracture mesomechanics, physical mesomechanics of materials, mesomechanics applications for geodynamics and tectonics, mesomechanics of smart materials and materials for electronics, non-destructive testing are viewed as suitable for publication.