Buckling of Defective Carbon Nanotubes Under Axial and Transverse Loads

Ziaee, Sima

doi:10.1142/s1758825114500045

Cited by 13 publications

(6 citation statements)

References 34 publications

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“…Equation (20) [42] proposes the relation between stresses and strains for outer surfaces:

\begin{eqnarray} \def\eqcellsep{&}\begin{array}{l} \tau _{\alpha \beta }^ \pm = \tau _0^ \pm {\delta _{\alpha \beta }} + \left( {\mu _0^ \pm - \tau _0^ \pm } \right)\left( {u_{\alpha ,\beta }^ \pm + u_{\beta ,\alpha }^ \pm } \right)\\[11pt] \quad +\, \left( {\lambda _0^ \pm + \tau _0^ \pm } \right)u_{\gamma ,\gamma }^ \pm {\delta _{\alpha \beta }} + \tau _0^ \pm u_{\alpha ,\beta }^ \pm \\[11pt] \tau _{\alpha 3}^ \pm = \tau _0^ \pm u_{3,\alpha }^ \pm \end{array} \end{eqnarray}

where “+” and “−” denote the nanoplate's top and bottom surfaces, respectively. μ 0 and λ 0 represent surface layer Lamé parameters, τ 0 denotes the residual surface stress, and

{u_{,\alpha }}

indicates the displacement field gradient in terms of the in‐plane directions.…”

Section: Modelling the Fluid–solid Interactionmentioning

confidence: 99%

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Investigation of the effect of viscosity and fluid flow on buckling behaviour of non‐local nanoplate with surface energy

Arpanahi,

Abdehvand,

Sheykhi

et al. 2023

The Journal of Engineering

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The buckling of a nanoplate at the bottom of a channel over which the fluid passes with a one-dimensional flow is investigated in this article. Navier-Stokes equations were used to obtain the applied force from the fluid to the nanoplate. Non-local elasticity theories and surface effects were used to consider nanoscale effects. By solving this problem using Galerkin's weighted residual method, interesting results were obtained. Applying nonlocality increases the fluid's impact on the buckling of a nanoplate. The lower modes are more noticeably affected by being placed in a fluid environment. Also, the presence of fluid and surface effects both increase the buckling capacity of the system. The obtained results are very helpful for developing and improving the performance of fluid-coupled nanostructures that have buckling potential.

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“…Equation (20) [42] proposes the relation between stresses and strains for outer surfaces:

\begin{eqnarray} \def\eqcellsep{&}\begin{array}{l} \tau _{\alpha \beta }^ \pm = \tau _0^ \pm {\delta _{\alpha \beta }} + \left( {\mu _0^ \pm - \tau _0^ \pm } \right)\left( {u_{\alpha ,\beta }^ \pm + u_{\beta ,\alpha }^ \pm } \right)\\[11pt] \quad +\, \left( {\lambda _0^ \pm + \tau _0^ \pm } \right)u_{\gamma ,\gamma }^ \pm {\delta _{\alpha \beta }} + \tau _0^ \pm u_{\alpha ,\beta }^ \pm \\[11pt] \tau _{\alpha 3}^ \pm = \tau _0^ \pm u_{3,\alpha }^ \pm \end{array} \end{eqnarray}

where “+” and “−” denote the nanoplate's top and bottom surfaces, respectively. μ 0 and λ 0 represent surface layer Lamé parameters, τ 0 denotes the residual surface stress, and

{u_{,\alpha }}

indicates the displacement field gradient in terms of the in‐plane directions.…”

Section: Modelling the Fluid–solid Interactionmentioning

confidence: 99%

“…The influence of axial and transverse loading and length on the carrying-load capacity of carbon nanotubes (CNTs) was studied by Ziaee [42] using the molecular structural mechanics technique.…”

Section: Introductionmentioning

confidence: 99%

Investigation of the effect of viscosity and fluid flow on buckling behaviour of non‐local nanoplate with surface energy

Arpanahi,

Abdehvand,

Sheykhi

et al. 2023

The Journal of Engineering

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“…They also indicated that the post-buckling deformation of the low-dimensional structures is strongly affected by the length, diameter and chirality of the nanostructures. Ziaee [2014] applied molecular structural mechanics to investigate the buckling properties of defective armchair and chiral SWCNTs under transverse and axial compression loading. He found that the position of the microscopic impurity in the structure of the low-dimensional material models plays a remarkable role on the change in the value of critical buckling force.…”

Section: Introductionmentioning

confidence: 99%

Numerical Analysis of the Structural Stability of Ideal (Defect-Free) and Structurally and Morphologically Degenerated Homogeneous, Linearly- and Angle-Adjoined Nanotubes and Cylindrical Fullerenes Under Axial Loading Using Finite Element Method

Yengejeh

Öchsner

Kazemi

et al. 2018

Int. J. Appl. Mechanics

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We report on the structural stability of ideal (defect-free) and structurally and morphologically degenerate carbon nanotubes and nanotube junction systems under axial loading based on the finite element method. We estimated the values for critical buckling load for uncapped and capped single-walled carbon nanotubes (SWCNTs) and linear and angle-adjoined SWCNT heterojunctions in ideal and structurally degenerate systems containing single-, double-, triple-, pinhole- and pentagon–heptagon (i.e., 5–7) structural defects and also containing a substitutional nitrogen (N) atom inclusion under compressive loading. Absolute atomic vacancy (defect) concentration in studied SWCNTs models was assumed to be nil for ideal systems, and was up to 3.0 at.% for structurally and morphologically degenerate systems. It was found that all types of structural defects and the morphological N-defect had reduced the load carrying capacity and mechanical strength in all SWCNT systems studied. The SWCNT models containing physically large vacant sites, such as triple- and pinhole-defects, displayed significantly lower critical load values compared to the systems that contained only a single-, double- or triple-vacancies. In addition, we found that capped SWCNTs performed marginally better in critical load carrying capacity compared to uncapped SWCNT systems. Furthermore, majority of the investigated structures displayed reduced load in SWCNTs with narrower tube widths, proportional to the size and the type of the defect investigated. The effects of chirality, such as zigzag- versus armchair-type, on the structural stability of the investigated SWCNT models were also investigated.

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“…Comparing with extensive investigation on the mechanical properties of CNTs and CNT-polymer composites [Odegard et al, 2003;Jiang et al, 2006;Chowdhury et al, 2014;Meng et al, 2014;Rafiee et al, 2014;Ziaee, 2014;], there are relative fewer studies devoting to interpreting the electrical conductivity mechanisms and investigating how the overall electrical properties of the composites vary with their constituent features from both the theoretical and experimental perspectives [Kim et al, 2005;Gojny et al, 2006;Li et al, 2007;Yan et al, 2007;Chang et al, 2009;Seidel and Lagoudas, 2009;Takeda et al, 2011]. It should be mentioned that most studies in the literature focused on investigating the electrical properties of the as-received composites without considering the stretching effects.…”

Section: Introductionmentioning

confidence: 99%

Micromechanics Modeling of Bi-Axial Stretching Effects on the Electrical Conductivity of CNT-Polymer Composites

Feng

Jiang

2015

Int. J. Appl. Mechanics

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In this paper, the bi-axial stretching effects on the electrical conductivity of carbon nanotube (CNT)-polymer composites are studied by a mixed micromechanics model with the consideration of the electrical conductive mechanisms. The bi-axial stretching effects are characterized by volume expansion of composite, re-orientation of CNTs and change of conductive networks. Simulation results demonstrate that the bi-axial stretching decreases the electrical conductivity of the composites due to the dominant role of the stretching-induced change in conductive networks, i.e., the increase in the percolation threshold, the separation distance among CNTs and the breakdown of the networks. It is also found that the bi-axial stretching enhances the decreasing rate of the electrical conductivity and increases the distribution randomness of the CNTs in the bi-axial stretching plane, as compared to a uni-axial stretching case. Furthermore, the dependency of the variation of electrical conductivity on the CNT concentration and sizes is also investigated. Possible reasons for the variation trends are interpreted. The study in this paper is expected to provide an increased understanding on the stretching effects upon the electrical conductivity of CNT-polymer composites.

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Buckling of Defective Carbon Nanotubes Under Axial and Transverse Loads

Cited by 13 publications

References 34 publications

Investigation of the effect of viscosity and fluid flow on buckling behaviour of non‐local nanoplate with surface energy

Investigation of the effect of viscosity and fluid flow on buckling behaviour of non‐local nanoplate with surface energy

Numerical Analysis of the Structural Stability of Ideal (Defect-Free) and Structurally and Morphologically Degenerated Homogeneous, Linearly- and Angle-Adjoined Nanotubes and Cylindrical Fullerenes Under Axial Loading Using Finite Element Method

Micromechanics Modeling of Bi-Axial Stretching Effects on the Electrical Conductivity of CNT-Polymer Composites

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