Mark Pollicott scite author profile

Let M be a pinched negatively curved Riemannian manifold, whose unit tangent bundle is endowed with a Gibbs measure m F associated with a potential F. We compute the Hausdorff dimension of the conditional measures of m F . We study the m F -almost sure asymptotic penetration behaviour of locally geodesic lines of M into small neighbourhoods of closed geodesics, and of other compact (locally) convex subsets of M. We prove Khintchine-type and logarithm law-type results for the spiraling of geodesic lines around these objects. As an arithmetic consequence, we give almost sure Diophantine approximation results of real numbers by quadratic irrationals with respect to general Hölder quasi-invariant measures.

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On the rate of mixing of Axiom A flows

Pollicott

1985

Invent Math

239

210

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w 0. IntroductionAxiom A systems were originally introduced by Smale in his seminal paper on dynamical systems [28]. One of their main purposes was to generalise Anosov systems (both diffeomorphisms and flows). Perhaps the most significant feature of this generalisation was that it further divorced the purely dynamical aspects of the system from the underlying geometry of the manifold. Even in such generality remarkably powerful results can still be obtained for Axiom A diffeomorphisms. For example, the rate of mixing of an Axiom A diffeomorphism is always exponential ([2], p. 38) and the zeta function for the diffeomorphism is rational [16]. However, for Axiom A flows the corresponding results are not always valid. For example, the rate of mixing for Axiom A flows need not be exponentially fast [22] and the zeta functions for these flows need not be meromorphic in the entire complex plane [12].The purpose of this paper is to actually relate the rate of mixing of an Axiom A flow to the meromorphic domain of its zeta function. In particular, we shall give necessary conditions for exponential mixing (which we also refer to as exponential decay of correlations). We shall also exhibit examples of Axiom A flows for which the rate of mixing can be chosen to be arbitrarily slow. In particular, this answers a question of Bowen regarding the possibility of polynomial rates of mixing for Axiom A flows ([-3], p. 31). Following the program advanced by Bowen and Ruelle [6] our first step is to reduce the problem to the case of suspended flows using the powerful and useful symbolic dynamics of Bowen [4]. The rate of decay of the so-called correlation function is then reflected in the analytic domain of its Fourier transform. (In particular, for exponential decay this is governed by the Paley-Wiener theorem ([15], p. 174)). Our approach is to relate domain of the Fourier Transform (for the case of the suspended flow) to the spectrum of an associated Ruelle operator acting on an appropriate Banach space. We then use previous work by the author to relate this spectrum to the domain of the zeta function for the flow (for both suspended flows and Axiom A flows) [-20]. We should point out that Parry and the author originally studied this zeta function in connection with Prime Orbit Theorems for Axiom A flows [19].In Sect. 1 we introduce our principle tool, the Ruelle operator. In Sect. 2 we recall some results on suspended flows and in Sect. 3 we introduce the zeta function and correlation functions for these flows. In the fourth section we prove our main result in the context of suspended flows. In the fifth section we introduce Axiom A flows and rephrase our results in this stronger setting. In Sect. 6 we give a simple counter-example to show that in general there is no order of mixing common to the class of all Axiom A flows. This paper was written while the author was enjoying the hospitality and financial support of the Institut des Hautes Etudes Scientifiques. I would like to express my gratitude to David Ruelle for his consid...

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An Analogue of the Prime Number Theorem for Closed Orbits of Axiom a Flows

Parry¹,

Pollicott²

1983

The Annals of Mathematics

224

171

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Anosov flows and dynamical zeta functions

2013

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We study the Ruelle and Selberg zeta functions for C r Anosov flows, r > 2, on a compact smooth manifold. We prove several results, the most remarkable being: (a) for C ∞ flows the zeta function is meromorphic on the entire complex plane; (b) for contact flows satisfying a bunching condition (e.g. geodesic flows on manifolds of negative curvature better than 1 9 -pinched) the zeta function has a pole at the topological entropy and is analytic in a strip to its left; (c) under the same hypotheses as in (b) we obtain sharp results on the number of periodic orbits. Our arguments are based on the study of the spectral properties of a transfer operator acting on suitable Banach spaces of anisotropic currents.

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Mark Pollicott

Logarithm Laws for Equilibrium States in Negative Curvature

On the rate of mixing of Axiom A flows

An Analogue of the Prime Number Theorem for Closed Orbits of Axiom a Flows

Anosov flows and dynamical zeta functions

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