Existence of Exotic rotation domains and Herman rings for quadratic H\'enon maps
Abstract
A quadratic H\'enon map is an automorphism of 2 of the form h:(x,y) (1/2 (x2+c)- y,x). It has a constant Jacobian equal to and has two fixed points. If λ is on the unit circle (one says h is conservative) these fixed points can be both elliptic or both hyperbolic. In the elliptic case, under an additional Diophantine condition, a simple application of Siegel Theorem shows that h admits quasi-periodic orbits with two frequencies in the neighborhood of its fixed points. Surprisingly, in some hyperbolic cases, Shigehiro Ushiki observed numerically what seems to be quasi-periodic orbits belonging to some ``Exotic rotation domains'' though no Siegel disk is associated to the fixed points. The aim of this paper is to explain and prove the existence of these ``Exotic rotation domains''. Our method also applies to the dissipative case (||<1) and allows to prove the existence of attracting Herman rings. The theoretical framework we develop permits to produce numerically these Herman rings that were never observed before.
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