The Robustness of a Collectively Encoded Rydberg Qubit

We demonstrate a collectively-encoded qubit based on a single Rydberg excitation - a Rydberg polariton - stored in an ensemble of N entangled atoms. Qubit rotations are performed by applying microwave fields that drive excitations between Rydberg states. Coherent read-out is preformed by mapping the polariton into a single photon. Ramsey interferometry is used to probe the coherence of the qubit, and test the robustness to external perturbations. We show that the Ramsey fringe visibility is independent of atom loss, and that dephasing due to electric field noise scales as the forth power of field amplitude. These results show that robust quantum information processing can be achieved via collective encoding using Rydberg polaritons, and hence this system could provide an attractive alternative coding strategies for quantum computation and networking.