Widely tunable solid-state source of single-photons matching an atomic transition

Hybrid quantum technologies aim to harness the best characteristics of multiple quantum systems, in a similar fashion that classical computers combine electronic, photonic, magnetic, and mechanical components. For example, quantum dots embedded in semiconductor nanowires can produce highly pure, deterministic, and indistinguishable single-photons with high repetition, while atomic ensembles offer robust photon storage capabilities and strong optical nonlinearities that can be controlled with single-photons. However, to successfully integrate quantum dots with atomic ensembles, one needs to carefully match the optical frequencies of these two platforms. Here, we propose and experimentally demonstrate simple, precise, reversible, broad-range, and local method for controlling the emission frequency of individual quantum dots embedded in tapered semiconductor nanowires and use it to interface with an atomic ensemble via single-photons matched to hyperfine transitions and slow-light regions of the cesium D1-line. Our approach allows linking together atomic and solid-state quantum systems and can potentially also be applied to other types of nanowire-embedded solid-state emitters, as well as to creating devices based on multiple solid-state emitters tuned to produce indistinguishable photons.