Non-boundedness of the number of super level domains of eigenfunctions

Abstract

Generalizing Courant's nodal domain theorem, the "Extended Courant property" is the statement that a linear combination of the first n eigenfunctions has at most n nodal domains. A related question is to estimate the number of connected components of the (super) level sets of a Neumann eigenfunction u. Indeed, in this case, the first eigenfunction is constant, and looking at the level sets of u amounts to looking at the nodal sets \u-a=0\, where a is a real constant. In the first part of the paper, we prove that the Extended Courant property is false for the subequilateral triangle and for regular N-gons (N large), with the Neumann boundary condition. More precisely, we prove that there exists a Neumann eigenfunction uk of the N-gon, with labelling k, 4 k 6, such that the set \uk = 1\ has (N+1) connected components. In the second part, we prove that there exists a metric g on T2 (resp. on S2), which can be chosen arbitrarily close to the flat metric (resp. round metric), and an eigenfunction u of the associated Laplace-Beltrami operator, such that the set \u = 1\ has infinitely many connected components. In particular the Extended Courant property is false for these closed surfaces. These results are strongly motivated by a recent paper by Buhovsky, Logunov and Sodin. As for the positive direction, in Appendix~B, we prove that the Extended Courant property is true for the isotropic quantum harmonic oscillator in R2.