Bending of multilayer nanomembranes

A. D. Drozdov; J. deClaville Christiansen

doi:10.1016/j.compstruct.2017.09.053

Bending of multilayer nanomembranes

A. D. Drozdov^*, J. deClaville Christiansen

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

2 Citations (Scopus)

Abstract

Governing equations are developed for bending of an elastic circular membrane under in-plane tension (prestress) and out-of-plane uniform pressure or concentrated force. These relations are applied to fitting observations on nanomembranes made of CVD-grown and mechanically exfoliated graphene, graphene oxides with various concentrations of defects, molybdenum disulfide, bismuth selenite, and tungsten diselenide. Good agreement is demonstrated between the experimental data and results of simulation. It is shown that the elastic modulus per layer of a multilayer membrane is independent of the number of layers n, whereas the prestress grows exponentially with n. Simple equations are suggested to describe the effect of defects in the crystalline structure of a nanomembrane on its mechanical properties. These equations and validated by comparison of the model predictions with observations of graphene oxide.

Original language	English
Journal	Composite Structures
Volume	182
Pages (from-to)	261-272
Number of pages	12
ISSN	0263-8223
DOIs	https://doi.org/10.1016/j.compstruct.2017.09.053
Publication status	Published - 15 Dec 2017

Keywords

Defects
Elastic properties
Graphene
Multilayer nanomembrane

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title = "Bending of multilayer nanomembranes",

abstract = "Governing equations are developed for bending of an elastic circular membrane under in-plane tension (prestress) and out-of-plane uniform pressure or concentrated force. These relations are applied to fitting observations on nanomembranes made of CVD-grown and mechanically exfoliated graphene, graphene oxides with various concentrations of defects, molybdenum disulfide, bismuth selenite, and tungsten diselenide. Good agreement is demonstrated between the experimental data and results of simulation. It is shown that the elastic modulus per layer of a multilayer membrane is independent of the number of layers n, whereas the prestress grows exponentially with n. Simple equations are suggested to describe the effect of defects in the crystalline structure of a nanomembrane on its mechanical properties. These equations and validated by comparison of the model predictions with observations of graphene oxide.",

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T1 - Bending of multilayer nanomembranes

AU - Drozdov, A. D.

AU - deClaville Christiansen, J.

PY - 2017/12/15

Y1 - 2017/12/15

N2 - Governing equations are developed for bending of an elastic circular membrane under in-plane tension (prestress) and out-of-plane uniform pressure or concentrated force. These relations are applied to fitting observations on nanomembranes made of CVD-grown and mechanically exfoliated graphene, graphene oxides with various concentrations of defects, molybdenum disulfide, bismuth selenite, and tungsten diselenide. Good agreement is demonstrated between the experimental data and results of simulation. It is shown that the elastic modulus per layer of a multilayer membrane is independent of the number of layers n, whereas the prestress grows exponentially with n. Simple equations are suggested to describe the effect of defects in the crystalline structure of a nanomembrane on its mechanical properties. These equations and validated by comparison of the model predictions with observations of graphene oxide.

AB - Governing equations are developed for bending of an elastic circular membrane under in-plane tension (prestress) and out-of-plane uniform pressure or concentrated force. These relations are applied to fitting observations on nanomembranes made of CVD-grown and mechanically exfoliated graphene, graphene oxides with various concentrations of defects, molybdenum disulfide, bismuth selenite, and tungsten diselenide. Good agreement is demonstrated between the experimental data and results of simulation. It is shown that the elastic modulus per layer of a multilayer membrane is independent of the number of layers n, whereas the prestress grows exponentially with n. Simple equations are suggested to describe the effect of defects in the crystalline structure of a nanomembrane on its mechanical properties. These equations and validated by comparison of the model predictions with observations of graphene oxide.

KW - Defects

KW - Elastic properties

KW - Graphene

KW - Multilayer nanomembrane

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U2 - 10.1016/j.compstruct.2017.09.053

DO - 10.1016/j.compstruct.2017.09.053

M3 - Journal article

AN - SCOPUS:85029821740

SN - 0263-8223

VL - 182

SP - 261

EP - 272

JO - Composite Structures

JF - Composite Structures

ER -

Bending of multilayer nanomembranes

Abstract

Keywords

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