Flow of the zeros of polynomials under iterated differentiation

Abstract

For a monic polynomial Qn of degree n, let Qn, k be its k-th derivative normalized to be monic. Under the only assumption that the sequence \Qn\ has a weak* limiting zero distribution (an empirical distribution of zeros) represented by a probability measure μ0 with compact support in the complex plane, we show that as n, k → ∞ such that k / n → t ∈(0,1), the Cauchy transform of the normalized zero-counting measure of the polynomials Qn, k converges in a neighborhood of infinity to an analytic function, uniquely determined by μ0 and t, that can be written as the Cauchy transform of a measure μt, not necessarily uniquely determined unless μ0 is supported on the real line. The family of these Cauchy transforms and, when well defined, the corresponding measures μt , t ∈(0,1), whose dependence on the parameter t can be interpreted as a flow of the zeros under iterated differentiation, has several interesting connections with the inviscid Burgers equation, the fractional free convolution of μ0, or a nonlocal diffusion equation governing the density of μt on R. We provide an elementary and unified approach that not only recovers, but also explains various phenomena observed in prior works - from Burgers-type PDEs to free probability limits.