Chains of compact cylinders for cusp-generic nearly integrable convex systems on A3

Abstract

This paper is the first of a series of three dedicated to a proof of the Arnold diffusion conjecture for perturbations of convex integrable Hamiltonian systems on A3=T3× R3. We consider systems of the form H(θ,r)=h(r)+f(θ,r), where h is a C strictly convex and superlinear function on R3 and f∈ C(A3), ≥2. Given e>Min\,h and a finite family of arbitrary open sets Oi in R3 intersecting h-1(e), a diffusion orbit associated with these data is an orbit of H which intersects each open set Oi=T3× Oi⊂A3. The first main result of this paper (Theorem I) states the existence (under cusp-generic conditions on f in Mather's terminology) of "chains of compact and normally hyperbolic invariant 3-dimensional cylinders" intersecting each Oi. Diffusion orbits drifting along these chains are then proved to exist in subsequent papers. The second main result (Theorem II) consists in a precise description of the hyperbolic features of classical systems (sum of a quadratic kinetic energy and a potential) on A2=T2×R2, which is a crucial step to prove Theorem I.