English

Degree-d-invariant laminations

Dynamical Systems 2019-06-14 v1

Abstract

Degree-dd-invariant laminations of the disk model the dynamical action of a degree-dd polynomial; such a lamination defines an equivalence relation on S1S^1 that corresponds to dynamical rays of an associated polynomial landing at the same multi-accessible points in the Julia set. Primitive majors are certain subsets of degree-dd-invariant laminations consisting of critical leaves and gaps. The space PM(d)\textrm{PM}(d) of primitive degree-dd majors is a spine for the set of monic degree-dd polynomials with distinct roots and serves as a parameterization of a subset of the boundary of the connectedness locus for degree-dd polynomials. The core entropy of a postcritically finite polynomial is the topological entropy of the action of the polynomial on the associated Hubbard tree. Core entropy may be computed directly, bypassing the Hubbard tree, using a combinatorial analogue of the Hubbard tree within the context of degree-dd-invariant laminations.

Keywords

Cite

@article{arxiv.1906.05324,
  title  = {Degree-d-invariant laminations},
  author = {William P. Thurston and Hyungryul Baik and Yan Gao and John H. Hubbard and Tan Lei and Kathryn A. Lindsey and Dylan P. Thurston},
  journal= {arXiv preprint arXiv:1906.05324},
  year   = {2019}
}

Comments

62 pages, 24 figures

R2 v1 2026-06-23T09:51:58.713Z