Publication: Size-dependent transverse and longitudinal vibrations of embedded carbon and silica carbide nanotubes by nonlocal finite element method
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Date
2020-04-06
Authors
Uzun, Büşra
Yaylı, Mustafa Özgür
Authors
Civalek, Ömer
Akgöz, Bekir
Journal Title
Journal ISSN
Volume Title
Publisher
Springer Heidelberg
Abstract
In this study, free vibration analyses of embedded carbon and silica carbide nanotubes lying on an elastic matrix are performed based on Eringen's nonlocal elasticity theory. These nanotubes are modeled as nanobeam and nanorod. Elastic matrix is considered as Winkler-Pasternak elastic foundation and axial elastic media for beam and rod models, respectively. The vibration formulations of the beam and rod are derived by utilizing Hamilton's principle. The obtained equations of motions are solved by the method of separation of variables and finite element-based Hermite polynomials for various boundary conditions. The effects of boundary conditions, system modeling, structural sizes such as length, cross-sectional sizes, elastic matrix, mode number, and nonlocal parameters on the natural frequencies of these nanostructures are discussed in detail. Moreover, the availability of size-dependent finite element formulation is investigated in the vibration problem of nanobeams/rods resting on an elastic matrix.
Description
Keywords
Beam model, Mechanical-properties, Nonlinear vibration, Integral elasticity, Boundary-conditions, Thermal vibration, Continuum models, Dynamic-analysis, Frequency, Microtubules
Citation
Civalek, Ö. vd. (2020). "Size-dependent transverse and longitudinal vibrations of embedded carbon and silica carbide nanotubes by nonlocal finite element method". European Physical Journal Plus,135, 4.