Ultrafast many-body dynamics of dense Rydberg gases and ultracold plasma
Abstract
Within femtoseconds the strong light field of an ultrashort laser pulse can excite and ionize a few thousand atoms in an ultracold quantum gas. Here we investigate the rich many-body dynamics unfolding in a $^{87}$Rb Bose-Einstein condensate after exposure to a single femtosecond laser pulse. By tuning the laser wavelength over the two-photon ionization threshold, we adjust the initial energy of the electrons and can thus investigate the transition from an ultracold plasma to a dense Rydberg gas. Our experimental setup provides access to the kinetic energy of the released electrons, which allows us to distinguish between bound, free and plasma electrons. The large bandwidth of the ultrashort laser pulse makes it possible to overcome the Rydberg blockade which fundamentally limits the density in excitation schemes with narrow-band lasers. To understand the many-body dynamics at the microscopic level, we employ molecular dynamics simulations where the electrons are modeled as individual particles including collisional ionization and recombination processes. We find that the ultrafast dynamics within the first few nanoseconds is responsible for the final distribution of free, bound and plasma electrons and agrees well with the experimental observation. We find distinctly different dynamics compared to the expected transition from an ultracold neutral plasma to a dense Rydberg gas.