Petroleum Chemistry.
Vol. 50.
2010.
P. 1-16
Simulation of deformation and fracture of graphene: Effect of size, defects and surface modification
The deformation and fracture of graphene under uniaxial tension is simulated in the framework of quantum mechanics. The deformation forces are calculated as energy gradients from a microscopic strain coordinate in the quantum mechanics approximation. The strain and fracture characteristics (Young's moduli, stiffness coefficients, critical forces and fracture stress) are calculated using macroscopic relations of the linear theory of elasticity. The emphasis in the work is on the analysis of the effect of model sizes, defects and surface modification on the strain characteristics of graphene. The simulation results are compared with available experimental data. © 2010.
Authors
Yanovsky Y.1
,
Nikitina E.A.
1
,
Karnet Y.1
,
Nikitin S.M.
1,
2,
3
Journal
Publisher
Springer New York LLC
Number of issue
5-6
Language
English
Pages
329-336
Status
Published
Link
Volume
13
Year
2010
Organizations
- 1 Institute of Applied Mechanics RAS, Moscow, 119991, Russian Federation
- 2 Skobeltsyn Institute of Nuclear Physics, Moscow State University, Moscow, 119991, Russian Federation
- 3 People's Friendship University of Russia, Moscow, 117198, Russian Federation
Keywords
Elastic modulus; Graphene; Quantum mechanics; Uniaxial deformation
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Other records
Russian Journal of Inorganic Chemistry.
IAPC Nauka/Interperiodica.
Vol. 55.
2010.
P. 866-875