Suppression of thermal smearing in a feedback-driven atomic size Josephson junction

The ultimate spatial limit to establish a Josephson coupling between two superconducting electrodes is an atomic-scale vacuum tunneling junction. The Josephson effect in such ultrasmall junctions has been widely used to study superconducting materials, providing a powerful probe of the spatial variations of the superfluid density. Furthermore, studies of the supercurrent and charging effects unveiled new, frequency dependent, switching dynamics and thermal processes emerging due to the small size of the junctions. However, the Cooper pair current magnitude was considerably reduced by thermal fluctuations. Here we show that a feedback element induces a time-dependent bistable regime which periodically restores the zero voltage state. We find that the time-averaged current within the bistable regime is independent of thermal smearing, opening new avenues to study superconducting phenomena at the nanoscale.