There are many classical results, related to the Denjoy-Wolff theorem, concerning the relationship between orbits of interior points and orbits of boundary points under iterates of holomorphic self-maps of the unit disc. Here, we address such questions in the very general setting of sequences ( F n ) of holomorphic maps between simply connected domains. We show that, while some classical results can be generalised, with an interesting dependence on the geometry of the domains, a much richer variety of behaviours is possible. One of our main results is new even in the classical setting. Our methods apply in particular to non -autonomous dynam- ical systems, when ( F n ) are forward compositions of holo- morphic maps, and to the study of wandering domains in holomorphic dynamics. The proofs use techniques from geometric function theory, measure theory and ergodic theory, and the construction of examples involves a 'weak independence' version of the second Borel-Cantelli lemma and the concept from ergodic theory of 'shrinking targets'. (c) 2024 Published by Elsevier Inc.
Boundary dynamics for holomorphic sequences, non-autonomous dynamical systems and wandering domains / Benini, A.; Evdoridou, V.; Fagella, N.; Rippon, P. J.; Stallard, G. M.. - In: ADVANCES IN MATHEMATICS. - ISSN 0001-8708. - 446:(2024). [10.1016/j.aim.2024.109673]
Boundary dynamics for holomorphic sequences, non-autonomous dynamical systems and wandering domains
Benini A.;
2024-01-01
Abstract
There are many classical results, related to the Denjoy-Wolff theorem, concerning the relationship between orbits of interior points and orbits of boundary points under iterates of holomorphic self-maps of the unit disc. Here, we address such questions in the very general setting of sequences ( F n ) of holomorphic maps between simply connected domains. We show that, while some classical results can be generalised, with an interesting dependence on the geometry of the domains, a much richer variety of behaviours is possible. One of our main results is new even in the classical setting. Our methods apply in particular to non -autonomous dynam- ical systems, when ( F n ) are forward compositions of holo- morphic maps, and to the study of wandering domains in holomorphic dynamics. The proofs use techniques from geometric function theory, measure theory and ergodic theory, and the construction of examples involves a 'weak independence' version of the second Borel-Cantelli lemma and the concept from ergodic theory of 'shrinking targets'. (c) 2024 Published by Elsevier Inc.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.