Optimal gradient estimates for conductivity problems with imperfect low-conductivity interfaces
Abstract
This paper studies field concentration between two nearly touching conductors separated by imperfect low-conductivity interfaces, modeled by Robin boundary conditions. It is known that for any sufficiently small interfacial bonding parameter γ > 0, the gradient remains uniformly bounded with respect to the separation distance . In contrast, for the perfect bonding case (γ = 0, corresponding to the perfect conductivity problem), the gradient may blow up as 0 at a rate depending on the dimension. In this work, we establish optimal pointwise gradient estimates that explicitly depend on both γ and in the regime where these parameters are small. These estimates provide a unified framework that encompasses both the previously known bounded case (γ > 0) and the singular blow-up scenario (γ = 0), thus furnishing a complete and continuous characterization of the gradient behavior throughout the transition in γ. The key technical achievement is the derivation of new regularity results for elliptic equations as γ0, along with a case dichotomy based on the relative sizes of γ and a distance function δ(x'). Our results hold for strictly relatively convex conductors in all dimensions n ≥ 2.
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