Energy absorption, free and forced vibrations of flexoelectric nanocomposite magnetostrictive sandwich nanoplates with single sinusoidal edge on the frictional torsional viscoelastic medium

Most studies on the nanoscale mainly focus on regular rectangular nanoplates, but according to the synthesis of nanostructures, the dynamic response of non-rectangular nanoplates is noticeable and there are not many works on these complex nanostructures. This work presents energy absorption, and for...

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Bibliographic Details
Published inArchives of Civil and Mechanical Engineering Vol. 23; no. 4; p. 223
Main Authors Chu, C., Shan, L., Al-Furjan, M. S. H., Farrokhian, A., Kolahchi, R.
Format Journal Article
LanguageEnglish
Published London Springer London 22.08.2023
Springer Nature B.V
Subjects
Boundary conditions
Civil Engineering
Damping
Deformation
Dynamic response
Electric fields
Energy absorption
Engineering
Equations of motion
Forced vibration
Free vibration
Graphene
Hamilton's principle
Investigations
Magnetic fields
Magnetostriction
Mathematical analysis
Mathematical models
Mechanical Engineering
Nanocomposites
Nanomaterials
Nanostructure
Original Article
Piezoelectricity
Robotics
Sine waves
Size effects
Structural Materials
Vibration
Viscoelasticity
Flexoelectric
Free and forced vibrations
Non-rectangular sandwich nanoplates
Magnetostrictive
Energy absorption
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Summary:Most studies on the nanoscale mainly focus on regular rectangular nanoplates, but according to the synthesis of nanostructures, the dynamic response of non-rectangular nanoplates is noticeable and there are not many works on these complex nanostructures. This work presents energy absorption, and forced and free vibrations of sandwich non-rectangular nanoplates with a single sinusoidal edge resting on a fractional torsional viscoelastic medium. The nanostructure is made from alumina reinforced by graphene platelets (GPLs) as a core covered by the flexoelectric and magnetostrictive materials as top and bottom layers, respectively. The consideration of size effects is derived from the innovative theory of local/nonlocal phenomena in a two-phase context. The Halpin–Tsai micromechanical and Kelvin–Voigt models are applied for the effective characteristics of the material in the nanocomposite layer and structural damping, respectively. Based on Hamilton’s principle and refined zigzag theory (RZT), the coupled electro-magneto-mechanical equations of motion are gained and analyzed by Galerkin’s and Newmark’s procedures. The effects of different components, including factors related to both the nonlocal and local phase fractions, the volume fraction of GPLs, various elastic mediums, electric field, structural damping, magnetic field, piezoelectric and flexoelectric effects on the absorption of energy, and forced and free vibrations of the sandwich nanostructure. Numerical simulations demonstrate that optimal energy absorption occurs when the flexoelectric factor is set to zero and the piezoelectric constant is non-zero but of opposite polarity. Additionally, it is concluded that when the coefficient of the local phase fraction is zero, increasing the nonlocal factor has more influence on the energy absorption and vibration of the nanostructure.
ISSN:2083-3318
1644-9665
2083-3318
DOI:10.1007/s43452-023-00756-x