English

Crack initiation in elastic bodies

Analysis of PDEs 2016-09-07 v1 Functional Analysis

Abstract

In this paper we study the crack initiation in a hyper-elastic body governed by a Griffith's type energy. We prove that, during a load process through a time dependent boundary datum of the type ttg(x)t \to t g(x) and in absence of strong singularities (this is the case of homogeneous isotropic materials) the crack initiation is brutal, i.e., a big crack appears after a positive time ti>0t_i>0. On the contrary, in presence of a point xx of strong singularity, a crack will depart from xx at the initial time of loading and with zero velocity. We prove these facts (largely expected by the experts of material science) for admissible cracks belonging to the large class of closed one dimensional sets with a finite number of connected components. The main tool we employ to address the problem is a local minimality result for the functional \Es(u,Γ):=\Omf(x,v)dx+k\hu(Γ), \Es(u,\Gamma):=\int_\Om f(x,\nabla v) dx+k\hu(\Gamma), where ΩR2\Omega \subseteq \R^2, k>0k>0 and ff is a suitable Carath\'eodory function. We prove that if the uncracked configuration uu of \Om\Om relative to a boundary displacement ψ\psi has uniformly weak singularities, then configurations (uΓ,Γ)(u_\Gamma,\Gamma) with \hu(Γ)\hu(\Gamma) small enough are such that \Es(u,)<\Es(uΓ,Γ)\Es(u,\emptyset)<\Es(u_\Gamma,\Gamma).

Cite

@article{arxiv.math/0510592,
  title  = {Crack initiation in elastic bodies},
  author = {Antonin Chambolle and Alessandro Giacomini and Marcello Ponsiglione},
  journal= {arXiv preprint arXiv:math/0510592},
  year   = {2016}
}