Non-equilibrium Dynamics of O(N) Nonlinear Sigma models: a Large-N approach

Abstract

We study the time evolution of the mass gap of the O(N) non-linear sigma model in 2+1 dimensions due to a time-dependent coupling in the large-N limit. Using the Schwinger-Keldysh approach, we derive a set of equations at large N which determine the time dependent gap in terms of the coupling. These equations lead to a criterion for the breakdown of adiabaticity for slow variation of the coupling leading to a Kibble-Zurek scaling law. We describe a self-consistent numerical procedure to solve these large-N equations and provide explicit numerical solutions for a coupling which starts deep in the gapped phase at early times and approaches the zero temperature equilibrium critical point gc in a linear fashion. We demonstrate that for such a protocol there is a value of the coupling g= gc dyn> gc where the gap function vanishes, possibly indicating a dynamical instability. We study the dependence of gc dyn on both the rate of change of the coupling and the initial temperature. We also verify, by studying the evolution of the mass gap subsequent to a sudden change in g, that the model does not display thermalization within a finite time interval t0 and discuss the implications of this observation for its conjectured gravitational dual as a higher spin theory in AdS4.