A mean-field theory of effective normal modes in the Fermi-Pasta-Ulam-Tsingou model
Abstract
We present a non-perturbative, mean-field theory for the Fermi-Pasta-Ulam-Tsingou model with quartic interaction, capturing the quasiperiodic features shown by the system at all energies in the thermodynamic limit. Starting from the true Hamiltonian H of the system with N degrees of freedom, we introduce a mean-field Hamiltonian H such that the difference hN=(H-H)/N, considered as a random variable with respect to the Gibbs measure, tends to zero as N∞, in probabilistic sense. The dynamics of the mean-field Hamiltonian H consists of N independent oscillation modes with renormalized frequencies k = ωk1+γ(), ωk being the frequency of the k-th normal mode of the linearized system, whereas γ() is an explicit function of the specific energy of the system. Analytical predictions drawn from the effective Langevin equations ruling the dynamics of such oscillation modes are successfully compared with the numerical data from the original Hamiltonian dynamics. Such a simple decomposition of the true dynamics into N effective normal modes holds at all energy scales, i.e. from the quasi-integrable regime to the strongly chaotic one.
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