The symmetries of affine K-systems and a program for centralizer rigidity
Abstract
Let Aff(X) be the group of affine diffeomorphisms of a closed homogeneous manifold X=G/B admitting a G-invariant Lebesgue-Haar probability measure μ. For f0∈ Aff(X), let Z∞(f0) be the group of C∞ diffeomorphisms of X commuting with f0. This paper addresses the question: for which f0∈ Aff(X) is Z∞(f0) a Lie subgroup of Diff∞(X)? Among our main results are the following. (1) If f0∈ Aff(X) is weakly mixing with respect to μ, then Z∞(f0)< Aff(X), and hence is a Lie group. (2) If f0∈ Aff(X) is ergodic with respect to μ, then Z∞(f0) is a (necessarily C0 closed) Lie subgroup of Diff∞(X) (although not necessarily a subgroup of Aff(X)). (3) If f0∈ Aff(X) fails to be a K-system with respect to μ, then there exists f∈ Aff(X) arbitrarily close to f0 such that Z∞(f) is not a Lie group, containing as a continuously embedded subgroup either the abelian group C∞c((0,1)) (under addition) or the simple group Diff∞c((0,1)) (under composition). (4) Considering perturbations of f0 by left translations, we conclude that f0 is stably ergodic if and only if the condition Z∞< Aff(X) holds in a neighborhood of f0 in Aff(X). (Note that by BS97, Dani77, f0∈ Aff(X) is stably ergodic in Aff(X) if and only if f0 is a K-system.) The affine K-systems are precisely those that are partially hyperbolic and essentially accessible, belonging to a class of diffeomorphisms whose dynamics have been extensively studied. In addition, the properties of partial hyperbolicity and accessibility are stable under C1-small perturbation, and in some contexts, essential accessibility has been shown to be stable under smooth perturbation. Considering the smooth perturbations of affine K-systems, we outline a full program for (local) centralizer rigidity.
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