An iterative finite difference scheme for buckling of graphene beam subject to axial compressive load

Author

Elgindi, Mohamed B. ; Dongming Wei ; Ghazy, Mohammed A.

Author_Institution

Texas A&M Univ. - Qatar, Doha, Qatar

fYear

2014

fDate

17-20 Feb. 2014

Firstpage

79

Lastpage

82

Abstract

In this paper buckling loads and modes of an Euler beam made of graphene are considered. An eigenvalue problem is formulated with an additional parameter representing material´s elastoplasticity. Analytical approximate solution using the perturbation method is presented. This approximate solution is used as a basis for an iterative finite difference scheme to develop a more accurate solution. Deflection at points along the beam are calculated using this iterative finite difference scheme. Convergence with good accuracy is achieved.

Keywords

buckling; eigenvalues and eigenfunctions; elastoplasticity; finite difference methods; graphene; iterative methods; perturbation theory; C; Euler beam; analytical approximate solution; axial compressive loading; eigen-value problem; elastoplasticity; graphene beam buckling; iterative finite difference scheme; perturbation method; point deflection; Force; Graphene; Load modeling; Materials; Strain; Stress;

fLanguage

English

Publisher

ieee

Conference_Titel

Biomedical Engineering (MECBME), 2014 Middle East Conference on

Conference_Location

Doha

Type

conf

DOI

10.1109/MECBME.2014.6783211

Filename

6783211