# Analytic structures and harmonic measure at bifurcation locus

**Authors:** Jacek Graczyk, Grzegorz \'Swi\k{a}tek

arXiv: 1904.09434 · 2019-05-07

## TL;DR

This paper investigates the conformal geometry and harmonic measure properties at the boundary of connectedness loci for unicritical polynomials, revealing new regularity results and the structure of boundary neighborhoods.

## Contribution

It establishes $C^{1+rac{eta}{d}-	ext{epsilon}}$-conformality of similarity maps at boundary points and links their derivatives to transversality functions, advancing understanding of boundary structures.

## Key findings

- Proves $C^{1+rac{eta}{d}-	ext{epsilon}}$-conformality of similarity maps.
- Shows derivatives of similarity maps relate to transversality functions.
- Explains how non-linear dynamics create hedgehog neighborhoods blocking boundary access.

## Abstract

We study conformal quantities at generic parameters with respect to the harmonic measure on the boundary of the connectedness loci ${\cal M}_d$ for unicritical polynomials $f_c(z)=z^d+c$. It is known that these parameters are structurally unstable and have stochastic dynamics. We prove $C^{1+\frac{\alpha}{d}-\epsilon}$-conformality, $\alpha = 2-\mbox{HD}\,({\cal J}_{c_0})$, of the parameter-phase space similarity maps $\Upsilon_{c_0}(z):\mathbb{C}\mapsto \mathbb{C}$ at typical $c_0\in \partial {\cal M}_d$ and establish that globally quasiconformal similarity maps $\Upsilon_{c_0}(z)$, $c_0\in \partial {\cal M}_d$, are $C^1$-conformal along external rays landing at $c_0$ in $\mathbb{C}\setminus {\cal J}_{c_0}$ mapping onto the corresponding rays of ${\cal M}_d$. This conformal equivalence leads to the proof that the $z$-derivative of the similarity map $\Upsilon_{c_0}(z)$ at typical $c_0\in \partial {\cal M}_d$ is equal to $1/{\cal T}'(c_0)$, where ${\cal T}(c_0)=\sum_{n=0}^{\infty}(D(f_{c_0}^n)(c_0))^{-1}$ is the transversality function.   The paper builds analytical tools for a further study of the extremal properties of the harmonic measure on $\partial {\cal M}_d$. In particular, we will explain how a non-linear dynamics creates abundance of hedgehog neighborhoods in $\partial {\cal M}_d$ effectively blocking a good access of $\partial {\cal M}_d $ from the outside.

## Full text

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## Figures

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## References

56 references — full list in the complete paper: https://tomesphere.com/paper/1904.09434/full.md

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Source: https://tomesphere.com/paper/1904.09434