Nanosecond super-resolved imaging of a single cold atom by stimulated emission depletion microscopy

As one of the most critical methods for optical super-resolved microscopy, stimulated emission depletion (STED) microscopy has been widely applied in biological and chemical fields, leading to the Nobel prize of 2014 in chemistry. In cold atomic systems, fast and high-resolution microscopy of individual atoms is crucial since it can provide direct information on the dynamics and correlations of the system. Here, we demonstrate nanosecond two-dimensional snapshots of a single trapped ion beyond the optical diffraction limit, by combining the main idea of STED with the quantum state transition control in cold atoms. We achieve a spatial resolution up to 175 nm and a time resolution up to 50 ns simultaneously using a NA=0.1 objective in the experiment, which is improved over ten times compared to direct fluorescence imaging. To show the potential of this method, we applied it to record the motion of the trapped ion and observe one cycle of the secular motion of the ion with a displacement detection sensitivity of 10 nm. Our method provides a powerful tool for probing particles' positions, momenta and correlations, as well as their dynamics in cold atomic systems.