English

Double-layer potentials, configuration constants and applications to numerical ranges

Functional Analysis 2025-03-28 v2 Complex Variables

Abstract

Given a compact convex planar domain Ω\Omega with non-empty interior, the classical Neumann's configuration constant cR(Ω)c_{\mathbb{R}}(\Omega) is the norm of the Neumann-Poincar\'e operator KΩK_\Omega acting on the space of continuous real-valued functions on the boundary Ω\partial \Omega, modulo constants. We investigate the related operator norm cC(Ω)c_{\mathbb{C}}(\Omega) of KΩK_\Omega on the corresponding space of complex-valued functions, and the norm a(Ω)a(\Omega) on the subspace of analytic functions. This change requires introduction of techniques much different from the ones used in the classical setting. We prove the equality cR(Ω)=cC(Ω)c_{\mathbb{R}}(\Omega) = c_{\mathbb{C}}(\Omega), the analytic Neumann-type inequality a(Ω)<1a(\Omega) < 1, and provide various estimates for these quantities expressed in terms of the geometry of Ω\Omega. We apply our results to estimates for the holomorphic functional calculus of operators on Hilbert space of the type p(T)KsupzΩp(z)\|p(T)\| \leq K \sup_{z \in \Omega} |p(z)|, where pp is a polynomial and Ω\Omega is a domain containing the numerical range of the operator TT. Among other results, we show that the well-known Crouzeix-Palencia bound K1+2K \leq 1 + \sqrt{2} can be improved to K1+1+a(Ω)K \leq 1 + \sqrt{1 + a(\Omega)}. In the case that Ω\Omega is an ellipse, this leads to an estimate of KK in terms of the eccentricity of the ellipse.

Keywords

Cite

@article{arxiv.2407.19049,
  title  = {Double-layer potentials, configuration constants and applications to numerical ranges},
  author = {Bartosz Malman and Javad Mashreghi and Ryan O'Loughlin and Thomas Ransford},
  journal= {arXiv preprint arXiv:2407.19049},
  year   = {2025}
}

Comments

Revised version

R2 v1 2026-06-28T17:55:09.756Z