On the multiplicity of periodic orbits and homoclinics near critical energy levels of Hamiltonian systems in R4

Abstract

We study two-degree-of-freedom Hamiltonian systems. Let us assume that the zero energy level of a real-analytic Hamiltonian function H:R4 R contains a saddle-center equilibrium point lying in a strictly convex sphere-like singular subset S0⊂ H-1(0). From previous work [de Paulo-Salom\~ao, Memoirs of the AMS] we know that for any small energy E>0, the energy level H-1(E) contains a closed 3-ball SE in a neighborhood of S0 admitting a singular foliation called 2-3 foliation. One of the binding orbits of this singular foliation is the Lyapunoff orbit P2,E contained in the center manifold of the saddle-center. The other binding orbit lies in the interior of SE and spans a one parameter family of disks transverse to the Hamiltonian vector field. In this article we show that the 2-3 foliation forces the existence of infinitely many periodic orbits and infinitely many homoclinics to P2,E in SE. Moreover, if the branches of the stable and unstable manifolds of P2,E inside SE do not coincide then the Hamiltonian flow on SE has positive topological entropy. We also present applications of these results to some classical Hamiltonian systems.