The peak heat flux conjecture for the first Dirichlet eigenmode of convex planar domains
Abstract
In this paper, we study the scale-invariant quantity \[G()=\|∂n u1\|L∞(∂)λ1,\]where u1 is the first L2-normalized Dirichlet Laplace eigenfunction of a Euclidean domain and λ1 is its eigenvalue. This is related to the peak boundary heat flux in the long time limit. For convex domains we prove that \|∂n u1\|L∞(∂) is upper-bounded by a (domain-independent) constant multiple of λ1. Using layer potentials, we derive shape-derivative formulae for efficient gradient computations. When combined with high-order Nystr\"om discretization, a fast boundary integral equation solver, and eigenvalue rootfinding, this allows us to numerically optimize G over a class of rounded polygonal discretized domains. Based on extensive numerical experiments, we then conjecture that, over the set of convex domains, G is maximized by the semidisk, with the peak flux at the center of the diameter. To lend analytical support to this conjecture, we prove that the semidisk is a critical point of G under infinitesimal perturbations of its circular arc.
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