Stress concentration for nonlinear insulated conductivity problem with adjacent inclusions

Abstract

A high-contrast two-phase nonlinear composite material with adjacent inclusions of m-convex shapes is considered for m>2. The mathematical formulation consists of the insulated conductivity problem with p-Laplace operator in Rd for p>1 and d≥2. The stress, which is the gradient of the solution, always blows up with respect to the distance between two inclusions as goes to zero. We first establish the pointwise upper bound on the gradient possessing the singularity of order -β with β=(1-α)/m for some α≥0, where α=0 if d=2 and α>0 if d≥3. In particular, we give a quantitative description for the range of horizontal length of the narrow channel in the process of establishing the gradient estimates, which provides a clear understanding for the applied techniques and methods. For d≥2, we further construct a supersolution to sharpen the upper bound with any β>(d+m-2)/(m(p-1)) when p>d+m-1. Finally, a subsolution is also constructed to show the almost optimality of the blow-up rate -1/\p-1,m\ in the presence of curvilinear squares. This fact reveals a novel dichotomy phenomena that the singularity of the gradient is uniquely determined by one of the convexity parameter m and the nonlinear exponent p except for the critical case of p=m+1 in two dimensions.