Understanding the non-equilibrium dynamics of quantum systems of many particles is a challenge that permeates all areas of modern physics. Whether in particle accelerator experiments, or in the development of new materials, one often encounters the problem of having a large number of particles which interact quantum mechanically with each other. If one smashes together clusters of particles (as is done in nuclear collisions), or suddenly disturbs, periodically kicks or induces currents, the system becomes unstable, and loses equilibrium. The interactions between particles when driven out of equilibrium, give rise to intricate collective phenomena.
In this project, we worked on developing and applying new theoretical techniques to study such non-equilibrium systems. The focus is in particular on quantum field theories, where the system may be described as a continuum rather than a discrete set of particles. We made significant progress by considering low-dimensional models which often can be solved exactly, providing an ideal platform to probe and understand non-equilibrium dynamics in a rigorous manner.