Effects of geometric variations on buckling properties of carbon nanostructures: A finite element analysis

Abstract: Critical Bucking Load (CBL) is one of the essential parameters to describe the mechanic stabilities of materials, e.g. the low-dimensional carbon nanostructures. While the CBL of pristine carbon nanotubes have been previously investigated using the quantum mechanics-based calculations, the effect of geometrical variation on the CBL of carbon nanomaterials is rarely reported since it need considerably large atomic models, which needs high computational cost. In this study, both the analytical and Finite Element… Show more

“…A micromechanical approach is more interesting to improve the limitations of these models [5]. Concerning the studies investigating the effects of geometrical parameters and their combinations, we can cite the study of Sam Daliri et al [6,7] who combined numerical and statistical analysis for the prediction of stress distribution and buckling of the cylindrical shell structures [8], analogous to humerus bone.…”

Micromechanical modeling of ductile fracture of human humerus

“…A micromechanical approach is more interesting to improve the limitations of these models [5]. Concerning the studies investigating the effects of geometrical parameters and their combinations, we can cite the study of Sam Daliri et al [6,7] who combined numerical and statistical analysis for the prediction of stress distribution and buckling of the cylindrical shell structures [8], analogous to humerus bone.…”

Micromechanical modeling of ductile fracture of human humerus