Quantitative characterization of stress concentration in the presence of closely spaced hard inclusions in two-dimensional linear elasticity

TL;DR

This paper precisely characterizes the stress concentration and gradient blow-up near closely spaced hard inclusions in 2D linear elasticity, establishing optimal bounds and introducing singular functions for analysis.

Contribution

It introduces singular functions to accurately capture the gradient blow-up behavior and proves the optimality of the blow-up rate bound in the Lamé system with inclusions.

Findings

Gradient blow-up rate is $oxed{ ext{epsilon}^{-1/2}}$.

Singular functions effectively describe stress concentration.

The bound on blow-up rate is proven to be optimal.

Abstract

In the region between close-to-touching hard inclusions, the stress may be arbitrarily large as the inclusions get closer. The stress is represented by the gradient of a solution to the Lam\'e system of linear elasticity. We consider the problem of characterizing the gradient blow-up of the solution in the narrow region between two inclusions and estimating its magnitude. We introduce singular functions which are constructed in terms of nuclei of strain and hence are solutions of the Lam\'{e} system, and then show that the singular behavior of the gradient in the narrow region can be precisely captured by singular functions. As a consequence of the characterization, we are able to regain the existing upper bound on the blow-up rate of the gradient, namely, $\epsilon^{-1/2}$ where $\epsilon$ is the distance between two inclusions. We then show that it is in fact an optimal bound by showing that there are cases where $\epsilon^{-1/2}$ is also a lower bound. This work is the first to completely reveal the singular nature of the gradient blow-up in the context of the Lam\'{e} system with hard inclusions. The singular functions introduced in this paper play essential roles to overcome the difficulties in applying the methods of previous works. Main tools of this paper are the layer potential techniques and the variational principle. The variational principle can be applied because the singular functions of this paper are solutions of the Lam\'{e} system.