Voronoi limit measures for iterates of constant-coefficient differential operators on rational functions with simple poles

Abstract

B gvad and H\"agg proved that for a rational function with simple poles, the zeros of successive derivatives accumulate on the Voronoi diagram of the pole set, and the normalized zero-counting measures converge to a canonical probability measure supported on this diagram. We extend this result from pure derivatives to iterates of an arbitrary monic constant-coefficient differential operator. Let h(z)=A(z)/B(z) be a reduced rational function, where B is monic of degree b2 with distinct zeros S=\z1,…,zb\, and let P(D)=Σj=0m cjDj be a monic constant-coefficient differential operator of order m1. After clearing denominators, we can write P(D)n(h)= An/Bmn+1 and study the zeros of the numerator polynomials An. If r:=\j:cj≠0\, then (after passing to the proper part of h when r>0) the associated zero-counting measures converge vaguely to m(b-1)bm-r\,μS, where μS is the B gvad--H\"agg probability measure supported on the Voronoi diagram VS. In particular, the limit is a probability measure exactly when P(D)=Dm; otherwise a proportion m-rbm-r of zeros escapes to infinity (in the sense of vague convergence). When r<m, the unshifted logarithmic potentials diverge, but an explicit factorial renormalization yields L1loc( C) convergence to a subharmonic limit with Riesz measure m(b-1)bm-r\,μS. Apart from this scalar factor, the limiting measure is determined solely by the pole configuration; the coefficients of P(D) affect only an additive constant in the limiting potential.