# Entire functions with prescribed singular values

**Authors:** Luka Boc Thaler

arXiv: 1908.06026 · 2020-07-06

## TL;DR

This paper introduces a new class of entire functions characterized by a recursive exponential relation, demonstrating their rich singular value sets and diverse dynamical behaviors, including functions with both empty and non-empty Fatou sets.

## Contribution

The paper defines the class $\\mathcal{E}$ of entire functions via a recursive exponential sequence, proves its density and closure properties, and shows it contains functions with varied dynamical properties.

## Key findings

- Every closed set containing 0 and at least one other point is a singular value set of some function in $\mathcal{E}$.
- The class $\mathcal{E}$ intersects with both Speiser and Eremenko-Lyubich classes.
- Functions in $\mathcal{E}$ can have either empty or non-empty Fatou sets.

## Abstract

We introduce a new class of entire functions $\mathcal{E}$ which consists of all $F_0\in\mathcal{O}(\mathbb{C})$ for which there exists a sequence $(F_n)\in \mathcal{O}(\mathbb{C})$ and a sequence $(\lambda_n)\in\mathbb{C}$ satisfying $F_n(z)=\lambda_{n+1}e^{F_{n+1}(z)}$ for all $n\geq 0$. This new class is closed under the composition and its is dense in the space of all non-vanishing entire functions. We prove that every closed set $V\subset \mathbb{C}$ containing the origin and at least one more point is the set of singular values of some locally univalent function in $\mathcal{E}$, hence this new class has non-trivial intersection with both the Speiser class and the Eremenko-Lyubich class of entire functions. As a consequence we provide a new proof of an old result by Heins which states that every closed set $V\subset\mathbb{C}$ is the set of singular values of some locally univalent entire function. The novelty of our construction is that these functions are obtained as a uniform limit of a sequence of entire functions, the process under which the set of singular values is not stable. Finally we show that the class $\mathcal{E}$ contains functions with an empty Fatou set and also functions whose Fatou set is non-empty.

## Full text

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## References

12 references — full list in the complete paper: https://tomesphere.com/paper/1908.06026/full.md

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Source: https://tomesphere.com/paper/1908.06026