单位圆盘的单价自映射的半群化

IF 0.8 4区数学 Q2 MATHEMATICS

Annales De L Institut Fourier Pub Date : 2020-02-19 DOI:10.5802/aif.3517

F. Bracci, Oliver Roth

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引用次数: 2

摘要

设$f$是单位圆盘的一价自映射。我们引入了一种称为｛\sl半群化｝的技术，该技术允许构造单位圆盘的全纯自映射的连续半群$（\ phi_t）$，其时间映射$\ phi_1$在某种意义上非常接近$f$。$f$的半粗化与$f$（椭圆、双曲、正阶抛物或零阶抛物）具有相同的类型，并且具有给定乘法器的$f$边界正则不动点集与$\phi_1$的对应集之间存在一一对应关系。此外，在$f$（因此$\phi_1$）没有内部不动点的情况下，收敛到Denjoy-Wolff点的轨道的斜率是相同的。该构造基于全纯模型、定位技术和Gromov双曲性。作为该构造的一个应用，我们证明了在非椭圆情况下，$f$的轨道与Denjoy-Wolff点不相切地收敛，当且仅当$f$中的Koenigs域相对于垂线“几乎对称”。

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Semigroup-fication of univalent self-maps of the unit disc

Let $f$ be a univalent self-map of the unit disc. We introduce a technique, that we call {\sl semigroup-fication}, which allows to construct a continuous semigroup $(\phi_t)$ of holomorphic self-maps of the unit disc whose time one map $\phi_1$ is, in a sense, very close to $f$. The semigrup-fication of $f$ is of the same type as $f$ (elliptic, hyperbolic, parabolic of positive step or parabolic of zero step) and there is a one-to-one correspondence between the set of boundary regular fixed points of $f$ with a given multiplier and the corresponding set for $\phi_1$. Moreover, in case $f$ (and hence $\phi_1$) has no interior fixed points, the slope of the orbits converging to the Denjoy-Wolff point is the same. The construction is based on holomorphic models, localization techniques and Gromov hyperbolicity. As an application of this construction, we prove that in the non-elliptic case, the orbits of $f$ converge non-tangentially to the Denjoy-Wolff point if and only if the Koenigs domain of $f$ is "almost symmetric" with respect to vertical lines.

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来源期刊

Annales De L Institut Fourier 数学-数学

CiteScore

1.70

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： The Annales de l’Institut Fourier aim at publishing original papers of a high level in all fields of mathematics, either in English or in French. The Editorial Board encourages submission of articles containing an original and important result, or presenting a new proof of a central result in a domain of mathematics. Also, the Annales de l’Institut Fourier being a general purpose journal, highly specialized articles can only be accepted if their exposition makes them accessible to a larger audience.