Nearly-optimal effective stability estimates around Diophantine tori of H\"older Hamiltonians

Abstract

We prove that the solutions of H\"older-differentiable Hamiltonian systems, associated to initial conditions in a small ball of radius >0 around a Lagrangian, (γ,τ)-Diophantine, quasi-periodic torus, are stable over a time tstab 1/(||1+-1τ+1| |-1), where >2d+1, ∈ R, is the regularity, and d is the number of degrees of freedom. In the finitely differentiable case (for integer ), this result improves the previously known effective stability bounds around Diophantine tori. Moreover, by a previous work based on the Anosov-Katok construction, it is known that for any >0 there exists a C-Hamiltonian, with 3, admitting a sequence of solutions starting at distance n 0 from a (γ,τ)-Diophantine torus that diffuse in a time of order tdiffn 1/(|n|1+-1τ+1+). Therefore the stability estimates that we show are optimal up to an arbitrarily small polynomial correction.