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An inclination lemma for normally hyperbolic manifolds with an application to diffusion

Published online by Cambridge University Press:  10 July 2014

LARA SABBAGH*
Affiliation:
Mathematics Institute, University of Warwick, UK email [email protected]

Abstract

Let ($M$, ${\rm\Omega}$) be a smooth symplectic manifold and $f:M\rightarrow M$ be a symplectic diffeomorphism of class $C^{l}$ ($l\geq 3$). Let $N$ be a compact submanifold of $M$ which is boundaryless and normally hyperbolic for $f$. We suppose that $N$ is controllable and that its stable and unstable bundles are trivial. We consider a $C^{1}$-submanifold ${\rm\Delta}$ of $M$ whose dimension is equal to the dimension of a fiber of the unstable bundle of $T_{N}M$. We suppose that ${\rm\Delta}$ transversely intersects the stable manifold of $N$. Then, we prove that for all ${\it\varepsilon}>0$, and for $n\in \mathbb{N}$ large enough, there exists $x_{n}\in N$ such that $f^{n}({\rm\Delta})$ is ${\it\varepsilon}$-close, in the $C^{1}$ topology, to the strongly unstable manifold of $x_{n}$. As an application of this ${\it\lambda}$-lemma, we prove the existence of shadowing orbits for a finite family of invariant minimal sets (for which we do not assume any regularity) contained in a normally hyperbolic manifold and having heteroclinic connections. As a particular case, we recover classical results on the existence of diffusion orbits (Arnold’s example).

Type
Research Article
Copyright
© Cambridge University Press, 2014 

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References

Arnold, V. I.. Instability of dynamical systems with several degrees of freedom. Sov. Math. Doklady 5 (1964), 581585.Google Scholar
Berger, P. and Bounemoura, A.. A geometrical proof of the persistence of normally hyperbolic submanifolds. Dyn. Syst. 28(4) (2013), 567581.CrossRefGoogle Scholar
Chaperon, M.. Stable manifolds and the Perron–Irwin method. Ergod. Th. & Dynam. Sys. 24(5) (2004), 13591394.CrossRefGoogle Scholar
Cresson, J.. Un 𝜆-lemme pour des tores partiellement hyperboliques. C. R. Acad. Sci. Paris Sér. I Math. 331(1) (2000), 6570.CrossRefGoogle Scholar
Cresson, J. and Wiggins, S.. A ${\it\lambda}$-lemma for normally hyperbolic invariant manifold, unpublished, 2005.Google Scholar
Delshams, A., de la Llave, R. and Seara, T. M.. A Geometric Mechanism for Diffusion in Hamiltonian Systems Overcoming the Large Gap Problem: Heuristics and Rigorous Verification on a Model (Memoirs of the American Mathematical Society, 179(844)). American Mathematical Society, Providence, RI, 2006.Google Scholar
Delshams, A. and Huguet, G.. A geometric mechanism of diffusion: rigorous verification in a priori unstable Hamiltonian systems. J. Differential Equations 250 (2011), 26012623.CrossRefGoogle Scholar
Fontich, E. and Martn, P.. Differentiable invariant manifolds for partially hyperbolic tori and a lambda lemma. Nonlinearity 13(5) (2000), 15611593.CrossRefGoogle Scholar
Gidea, M. and Robinson, C.. Shadowing orbits for transition chains of invariant tori alternating with Birkhoff zones of instability. Nonlinearity 20(5) (2007), 11151143.CrossRefGoogle Scholar
Gidea, M. and Robinson, C.. Obstruction argument for transition chains of tori interspersed with gaps. Discrete Contin. Dyn. Syst. Ser. S 2(2) (2009), 393416.Google Scholar
Gidea, M. and Marco, J.-P.. Diffusion orbits along chains of hyperbolic cylinders. Preprint.Google Scholar
Hirsch, M. W., Pugh, C. C. and Shub, M.. Invariant Manifolds (Lecture Notes in Mathematics, 583). Springer-Verlag, Berlin, 1977.CrossRefGoogle Scholar
Lochak, P., Marco, J.-P. and Sauzin, D.. On the Splitting of Invariant Manifolds in Multidimensional Near-Integrable Hamiltonian Systems (Memoirs of the American Mathematical Society, 163(775)). American Mathematical Society, Providence, RI, 2003.CrossRefGoogle Scholar
Marco, J.-P.. Transition le long de chanes de tores invariants pour les systmes Hamiltoniens analytiques. Ann. Inst. H. Poincaré 64(2) (1996), 205252.Google Scholar