Multiscale Mass-Spring Models of Carbon Nanotube Arrays Accounting for Mullins-like Behavior and Permanent Deformation

Abstract

Based on a one-dimensional discrete system of bistable springs, a mechanical model is introduced to describe plasticity and damage in carbon nanotube (CNT) arrays. The energetics of the mechanical system are investigated analytically, the stress-strain law is derived, and the mechanical dissipation is computed, both for the discrete case as well as for the continuum limit. An information-passing approach is developed that permits the investigation of macroscopic portions of the material. As an application, the simulation of a cyclic compression experiment on real CNT foam is performed, considering both the material response during the primary loading path from the virgin state and the damaged response after preconditioning.

Read More: http://epubs.siam.org/doi/abs/10.1137/12087311X

ICB Affiliated Authors

Authors
T. Blesgen, F. Fraternali, J. R. Raney, and C. Daraio
Date
Type
Peer-Reviewed Article
Volume
11
Pages
545-565
Emblems