Mechanics of self-folding of single-layer graphene

Xianhong Meng; Ming Li; Zhan Kang; Xiaopeng Zhang; Jianliang Xiao

doi:10.1088/0022-3727/46/5/055308

Mechanics of self-folding of single-layer graphene

Xianhong Meng
, Ming Li^*
, Zhan Kang
, Xiaopeng Zhang
, Jianliang Xiao

^*Corresponding author for this work

School of Aeronautic Science and Engineering

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

83 Scopus citations

Abstract

The extreme out-of-plane flexibility makes single-layer graphene vulnerable to self-folding, driven by van der Waals interactions. Racket shaped bilayer graphene edges form after self-folding, which can significantly affect the electrical properties of graphenes. To study the self-folding behaviour, a theoretical model based on finite deformation beam theory is established. The critical folding lengths for both metastable and stable self-folding, as well as the edge profile of a folded single-layer graphene, are given. They all agree very well with MD simulations. MD simulations also show that folding directions do not have strong influence on the shape of folded graphene edges.

Original language	English
Article number	055308
Journal	Journal of Physics D: Applied Physics
Volume	46
Issue number	5
DOIs	https://doi.org/10.1088/0022-3727/46/5/055308
State	Published - 6 Feb 2013

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title = "Mechanics of self-folding of single-layer graphene",

abstract = "The extreme out-of-plane flexibility makes single-layer graphene vulnerable to self-folding, driven by van der Waals interactions. Racket shaped bilayer graphene edges form after self-folding, which can significantly affect the electrical properties of graphenes. To study the self-folding behaviour, a theoretical model based on finite deformation beam theory is established. The critical folding lengths for both metastable and stable self-folding, as well as the edge profile of a folded single-layer graphene, are given. They all agree very well with MD simulations. MD simulations also show that folding directions do not have strong influence on the shape of folded graphene edges.",

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AU - Meng, Xianhong

AU - Li, Ming

AU - Kang, Zhan

AU - Zhang, Xiaopeng

AU - Xiao, Jianliang

PY - 2013/2/6

Y1 - 2013/2/6

N2 - The extreme out-of-plane flexibility makes single-layer graphene vulnerable to self-folding, driven by van der Waals interactions. Racket shaped bilayer graphene edges form after self-folding, which can significantly affect the electrical properties of graphenes. To study the self-folding behaviour, a theoretical model based on finite deformation beam theory is established. The critical folding lengths for both metastable and stable self-folding, as well as the edge profile of a folded single-layer graphene, are given. They all agree very well with MD simulations. MD simulations also show that folding directions do not have strong influence on the shape of folded graphene edges.

AB - The extreme out-of-plane flexibility makes single-layer graphene vulnerable to self-folding, driven by van der Waals interactions. Racket shaped bilayer graphene edges form after self-folding, which can significantly affect the electrical properties of graphenes. To study the self-folding behaviour, a theoretical model based on finite deformation beam theory is established. The critical folding lengths for both metastable and stable self-folding, as well as the edge profile of a folded single-layer graphene, are given. They all agree very well with MD simulations. MD simulations also show that folding directions do not have strong influence on the shape of folded graphene edges.

UR - https://www.scopus.com/pages/publications/84872566253

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DO - 10.1088/0022-3727/46/5/055308

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VL - 46

JO - Journal of Physics D: Applied Physics

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ER -

Mechanics of self-folding of single-layer graphene

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