A Ruelle-McMullen formula for the volume dimension of skew products in $\mathbb C^2$

TL;DR

This paper extends Ruelle and McMullen's formulas to higher-dimensional holomorphic skew products in ^2, providing an explicit second-order expansion of the volume dimension of Julia sets as parameters vary.

Contribution

It introduces a second-order expansion formula for the volume dimension of Julia sets in skew products, generalizing classical results to higher dimensions.

Findings

Explicit second-order expansion of volume dimension as parameters tend to zero.

Characterization of volume dimension as zero of a pressure function.

Application to families of holomorphic skew products in ^2.

Abstract

Ruelle gave an explicit second-order expansion at $c=0$ of the Hausdorff dimension of the Julia set of the quadratic family $f_c(z)=z^2+c$. McMullen later extended this result to polynomial perturbations of $z^d$ for arbitrary degree $d\geq 2$. In this paper we study an analogue of this problem for skew products in $\mathbb C^2$. Since holomorphic dynamical systems in higher dimensions are non-conformal, we replace the Hausdorff dimension by the \emph{volume dimension}, a dynamically defined notion we introduced in our earlier work and characterized as the zero of a natural pressure function. We consider families of holomorphic skew products of the form \[ f_t(z,w)=(z^d, w^d+t(c_1 (z) w^{d-1} +c_2(z)w^{d-2} + \cdots+c_d(z))). \] Our main result gives an explicit second-order expansion of the volume dimension of the Julia set $J(f_t)$ as $t\to0$ in terms of the coefficients $c_k(z)$.