Dynamical transitions between equilibria in a dissipative Klein–Gordon lattice

Abstract

We consider the energy landscape of a dissipative Klein–Gordon lattice with a ϕ 4 on-site potential. Our analysis is based on suitable energy arguments, combined with a discrete version of the Łojasiewicz inequality, in order to justify the convergence to a single, nontrivial equilibrium for all initial configurations of the lattice. Then, global bifurcation theory is explored, to illustrate that in the discrete regime all linear states lead to nonlinear generalizations of equilibrium states. Direct numerical simulations reveal the rich structure of the equilibrium set, consisting of non-trivial topological (kink-shaped) interpolations between the adjacent minima of the on-site potential, and the wealth of dynamical convergence possibilities. These dynamical evolution results also provide insight on the potential stability of the equilibrium branches, and glimpses of the emerging global bifurcation structure, elucidating the role of the interplay between discreteness, nonlinearity and dissipation. • Analysis of the dynamical transitions between equilibria in a dissipative Klein–Gordon lattice. • Application of a discrete variant of Łojasiewicz inequality. • Applications of the global bifurcation theorem in discrete set-ups. • Numerical simulations reveal the rich structure of the equilibrium set and relevant bifurcations.