On the Mechanical Properties of Chiral Carbon Nanotubes

Carbon nanotubes (cnts) are specific structures with valuable characteristics. in general, the structure of each nanotube is defined by a unique chiral vector. in this paper, different structures of short single-walled cnts are simulated and their mechanical properties are determined using finite element method. for this aim, a simple algorithm is presented which is able to model the geometry of single-walled cnts with any desired structure based on nano-scale continuum mechanics approach. by changing the chiral angle from 0 to 30 degree for constant length to radius ratio, the effect of nanotube chirality on its mechanical properties is evaluated. it is observed that the tensile modulus of cnts changes between 0.93-1.02 tpa for different structures, and it can be higher for chiral structures than zigzag and armchair ones. also, for different chiral angles, the bending modulus changes between 0.76-0.82 tpa, while the torsional modulus varies in the range of 0.283-0.301tpa.