Functional Equations and Pole Structure of the Bartholdi Zeta Function

Abstract

In this paper, we investigate the Bartholdi zeta function on a connected simple digraph with nV vertices and nE edges. We derive a functional equation for the Bartholdi zeta function ζG(q,u) on a regular graph G with respect to the bump parameter u. We also find an equivalence between the Bartholdi zeta function with a specific value of u and the Ihara zeta function at u=0. We determine bounds of the critical strip of ζG(q,u) for a general graph. If G is a (t+1)-regular graph, the bounds are saturated and q=(1-u)-1 and q=(t+u)-1 are the poles at the boundaries of the critical strip for u 1, -t. When G is the regular graph and the spectrum of the adjacency matrix satisfies a certain condition, ζG(q,u) satisfies the so-called Riemann hypothesis. For u 1, q=(1-u)-1 are poles of ζG(q,u) unless G is tree. Although the order of the pole at q=(1-u)-1 is nE-nV+1 if u u* 1-nEnV, it is enhanced at u=u*. In particular, if the Moore-Penrose inverse of the incidence matrix L+ and the degree vector d satisfy the condition |L+ d|2 nE, the order of the pole at q=(1-u)-1 increases only by one at u=u*. The order of the pole at q=-(1-u)-1 coincides with that at q=(1-u)-1 if G is bipartite and is nE-nV otherwise.