Generation of off-critical zeros for hypercubic Epstein zeta-functions

Abstract

We study the Epstein zeta-function formulated on the d-dimensional hypercubic lattice, ζ(d)(s) = (1/2)'Σn1,…,nd (n12+·s+nd2)-s/2 where (s)>d and the summation runs over all integers excluding the origin. An analytical continuation of the Epstein function to the whole complex s-plane is constructed for spatial dimension d being a continuous variable ranging from 0 to ∞. We are interested in zeros =x+ iy defined by ζ(d)() = 0. Besides the trivial zeros, there exist "critical" zeros (on the critical line) with x=d2 and "off-critical" zeros (off the critical line) with x d2. Our numerical results reveal that critical zeros form closed or semi-open curves y(d) which enclose disjunctive regions of the complex plane (x= d/2,y). Each curve involves a number of left/right edge points *, defined by an infinite tangent dy/ dd*, which give rise to two conjugate tails of off-critical zeros with continuously varying dimension d. The curves of critical and off-critical zeros exhibit a singular expansion around edge points whose derivation resembles to the one around a critical point of mean-field type (with exponent 1/2 for the order parameter) in many-body statistical models. Further it turns out that for each d>9.24555… there exists a conjugate pair of real off-critical zeros which tend to the boundaries 0 and d of the critical strip in the limit d∞. As a by-product of the formalism, we derive an exact result for d 0 ζ(d)(s)/d and an equidistant distribution of critical zeros along the imaginary axis in the limit d∞.