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Bibliographic Details
Main Authors: Dong, Hongjie, Li, Haigang, Zhao, Yan
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.10615
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Table of Contents:
  • 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 $\varepsilon$. In contrast, for the perfect bonding case ($γ= 0$, corresponding to the perfect conductivity problem), the gradient may blow up as $\varepsilon \to 0$ at a rate depending on the dimension. In this work, we establish optimal pointwise gradient estimates that explicitly depend on both $γ$ and $\varepsilon$ 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 $γ\to0$, 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 $n \geq 2$.