Combining two earlier methods, our group at FU Berlin developed a numerical technique to simulate models of quantum field theory. One of these models is the so-called quantum sine-Gordon model, which has important applications in ultracold atom experiments. The new method was able to generate new results for physical characteristics of this model both at equilibrium and out of equilibrium.
Moreover, in collaboration with the “AtomChip” experimental group at TU Wien, we studied two physical properties of matter as seen through ultracold atom experiments. The information needed to fully characterise the state of a system of particles at equilibrium is theoretically expected to be limited according to what is known as “area law”. Using a technique to extract the full information content of an ultracold atom system, we helped to observe this theoretical limit experimentally. On the other hand, when such systems are driven out of equilibrium by some abrupt change, the information of this change propagates through the system at a characteristic speed, as if it was carried by travelling particles. When the density of the atoms varies from point to point, the characteristic speed varies as well. Developing theoretical tools we helped to experimentally observe how the variation of the characteristic speed affects the propagation of information, in analogy to how light trajectories bend in curved spacetime as predicted by the general theory of relativity.