Urschel Nodal Domains via Perturbation Theory

Abstract

We prove several types of Courant nodal domain theorems for generalized Laplacians on graphs, based on an invariant introduced by Urschel, which we call the "Urschel number", denoted UN( f), of an eigenvector f. We refine Urschel's invariant, and use perturbation techniques to obtain some new results. First, we show the existence of mutually orthogonal eigenvectors, such that if the k-th eigenvalue has multiplicity m, then for 0 j m-1, UN( fk+j) k+(j,(m-1)-j). Second, for a simple k-th eigenvalue, we classify the zeroes of fk as either "shallow or "deep"; we obtain a number of results that say, roughly speaking, the more shallow vertices fk has, the more control we have over our new invariants based on Urschel's. Our new invariants of an eigenvector, fk, are a sequence of integers whose minimum value is UN( fk) and whose maximum, denoted UN( fk), is the maximum number of nodal domains of any possible positive/negative signing or "charge" of the zeroes of fk. An example of our second type of result is that if fk has no deep vertices, then UN( fk) k. We provide a number of examples to illustrate our main results, and how they differ from the situation in analysis. We also describe a minor improvement of the Gladwell-Zhu theorem for an orthonormal eigenbasis in the presence of eigenvalues of sufficient multiplicity.