Nonlocal dynamic modeling of mass sensors consisting of graphene sheets based on strain gradient theory

Sadok Mehrez; Saeed Ali Karati; Parnia Taheri DolatAbadi; S. N.R. Shah; Sikander Azam; Majid Khorami; Hamid Assilzadeh

doi:10.12989/anr.2020.9.4.221

Nonlocal dynamic modeling of mass sensors consisting of graphene sheets based on strain gradient theory

Sadok Mehrez
, Saeed Ali Karati
, Parnia Taheri DolatAbadi
, S. N.R. Shah
, Sikander Azam
, Majid Khorami
, Hamid Assilzadeh

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

The following composition establishes a nonlocal strain gradient plate model that is essentially related to mass sensors laying on Winkler-Pasternak medium for the vibrational analysis from graphene sheets. To achieve a seemingly accurate study of graphene sheets, the posited theorem actually accommodates two parameters of scale in relation to the gradient of the strain as well as non-local results. Model graphene sheets are known to have double variant shear deformation plate theory without factors from shear correction. By using the principle of Hamilton, to acquire the governing equations of a non-local strain gradient graphene layer on an elastic substrate, Galerkin’s method is therefore used to explicate the equations that govern various partition conditions.

Original language	English
Pages (from-to)	221-235
Number of pages	15
Journal	Advances in Nano Research
Volume	9
Issue number	4
DOIs	https://doi.org/10.12989/anr.2020.9.4.221
State	Published - Nov 2020

Keywords

graphene sheets
mass sensor
nonlocal strain gradient
refined plate theory
vibration

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10.12989/anr.2020.9.4.221

Cite this

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title = "Nonlocal dynamic modeling of mass sensors consisting of graphene sheets based on strain gradient theory",

abstract = "The following composition establishes a nonlocal strain gradient plate model that is essentially related to mass sensors laying on Winkler-Pasternak medium for the vibrational analysis from graphene sheets. To achieve a seemingly accurate study of graphene sheets, the posited theorem actually accommodates two parameters of scale in relation to the gradient of the strain as well as non-local results. Model graphene sheets are known to have double variant shear deformation plate theory without factors from shear correction. By using the principle of Hamilton, to acquire the governing equations of a non-local strain gradient graphene layer on an elastic substrate, Galerkin{\textquoteright}s method is therefore used to explicate the equations that govern various partition conditions.",

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AU - Mehrez, Sadok

AU - Karati, Saeed Ali

AU - DolatAbadi, Parnia Taheri

AU - Shah, S. N.R.

AU - Azam, Sikander

AU - Khorami, Majid

AU - Assilzadeh, Hamid

PY - 2020/11

Y1 - 2020/11

N2 - The following composition establishes a nonlocal strain gradient plate model that is essentially related to mass sensors laying on Winkler-Pasternak medium for the vibrational analysis from graphene sheets. To achieve a seemingly accurate study of graphene sheets, the posited theorem actually accommodates two parameters of scale in relation to the gradient of the strain as well as non-local results. Model graphene sheets are known to have double variant shear deformation plate theory without factors from shear correction. By using the principle of Hamilton, to acquire the governing equations of a non-local strain gradient graphene layer on an elastic substrate, Galerkin’s method is therefore used to explicate the equations that govern various partition conditions.

AB - The following composition establishes a nonlocal strain gradient plate model that is essentially related to mass sensors laying on Winkler-Pasternak medium for the vibrational analysis from graphene sheets. To achieve a seemingly accurate study of graphene sheets, the posited theorem actually accommodates two parameters of scale in relation to the gradient of the strain as well as non-local results. Model graphene sheets are known to have double variant shear deformation plate theory without factors from shear correction. By using the principle of Hamilton, to acquire the governing equations of a non-local strain gradient graphene layer on an elastic substrate, Galerkin’s method is therefore used to explicate the equations that govern various partition conditions.

KW - graphene sheets

KW - mass sensor

KW - nonlocal strain gradient

KW - refined plate theory

KW - vibration

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M3 - Article

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JO - Advances in Nano Research

JF - Advances in Nano Research

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ER -

Nonlocal dynamic modeling of mass sensors consisting of graphene sheets based on strain gradient theory

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Keywords

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