Resonant excitation of the bushes of nonlinear vibrational modes in monoatomic chains

Abstract: Intermode interactions in one-dimensional nonlinear periodic structures have been studied by many authors, starting with the classic work by Fermi, Pasta, and Ulam (FPU) in the middle of the last century. However, symmetry selection rules for the energy transfer between nonlinear vibrational modes of different symmetry, which lead to the possibility of excitation of some bushes of such modes, were not revealed. Each bush determines an exact solution of nonlinear dynamical equations of the considered system. The collection of modes of a given bush does not change in time, while there is a continuous energy exchange between these modes. Bushes of nonlinear normal modes (NNMs) are constructed with the aid of group-theoretical methods and therefore they can exist for cases with large-amplitude atomic vibrations and for any type of interatomic interactions. In most publications, bushes of NNMs or similar dynamical objects in one-dimensional systems are investigated under periodic boundary conditions. In this paper, we present a study of bushes of NNMs in monoatomic chains for the case of fixed boundary conditions, which sheds light on a series of new properties of intermode interactions in such systems, as well as a method for constructing bushes of NNMs by continuation of conventional normal modes to the case of large atomic oscillations. The present study was carried out for the chains with the Lennard-Jones interatomic potential, but methods developed in this paper are valid for arbitrary monoatomic chains.