Interplay between critical and off-critical zeros of two-dimensional Epstein zeta functions

Abstract

The two-dimensional Epstein zeta function formulated on a rectangular lattice with spacings ax=1 and ay=, ζ(2)(s,) = 12 Σj,k (j2+2 k2)-s ((s)>1) where the sum goes over all integers except of the origin (j,k)=(0,0), is studied. It can be analytically continued to the whole complex s-plane except for the point s=1. The nontrivial zeros \ =x+ iy \ of the Epstein zeta function, defined by ζ(2) (,)=0, split into ``critical'' zeros (on the critical line x=12) and ``off-critical'' zeros (x12). According to the present numerical calculation, the critical zeros form open or closed curves y() in the plane (,y). Two nearest critical zeros merge at special points, referred to as left/right edge zeros, which are defined by a divergent tangent dy/ d*. Each of these edge zeros gives rise to a continuous curve of off-critical zeros which can thus be generated systematically. As a rule, each curve of off-critical zeros joins a pair of left and right edge zeros. It is shown that in the regions of small/large values of the anisotropy parameter the Epstein zeta function can be approximated adequately by a function which reveals an equidistant distribution of critical zeros along the imaginary axis in the limits 0 and ∞. It is also found that for each ∈ (0,c*] [1/c*,∞) with c*≈ 0.141733 there exists a pair of real off-critical zeros, their x components go to the borders 0 and 1 of the critical region in the limits 0,∞. As a rule, each curve of off-critical zeros joins a pair of left and right edge zeros.

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