The heat trace for domains with curved corners

Abstract

The heat trace of a planar polygon contains corner terms depending only on the opening angles, while the heat trace of a smooth planar domain contains curvature terms along the boundary. We show that, for curvilinear polygons, these two phenomena first interact at order t1/2. We compute this first corner-curvature heat invariant and prove a sharp sign law for its Dirichlet angular factor: its sign is determined solely by whether the corner is convex or reflex. More precisely, we derive the local heat trace expansion through order t1/2, for both Dirichlet and Neumann boundary conditions. The new coefficient decomposes into the usual smooth-boundary contribution and a sum of local curved-corner terms, each depending only on the interior angle α and the one-sided limiting curvatures κ of the adjacent arcs. In the Dirichlet case, the curved-corner contribution has the form C1/2(α,κ+,κ-) = c1/2(α)κ+ + κ-4(α/2), with c1/2(α) given by an explicit sector heat kernel integral. We determine its sign for every 0<α<2π. The sign law has a spectral consequence: it gives a new obstruction to a curvilinear polygon being Dirichlet-isospectral to a straight-sided polygon. In particular, every convex curvilinear polygon Dirichlet-isospectral to a straight-sided polygon must itself be straight-sided, removing the assumption of straight corners from the theorem of Enciso and Gómez-Serrano.