A fiber-integrated quantum memory for telecom light

Abstract

We demonstrate the storage and on-demand retrieval of single-photon-level telecom pulses in a fiber cavity. The cavity is formed by fiber Bragg gratings at either end of a single-mode fiber. Photons are mapped into, and out of, the cavity using quantum frequency conversion driven by intense control pulses. In a first, spliced-fiber, cavity we demonstrate storage up to 0.55μs (11 cavity round trips), with 11.3 0.1% total memory efficiency, and a signal-to-noise ratio of 12.8 after 1 round trip. In a second, monolithic cavity, we increase this lifetime to 1.75μs (35 round trips) with a memory efficiency of 12.7 0.2% (SNR of 7.0 0.2) after 1 round trip. Fiber-based cavities for quantum storage at telecom wavelengths offer a promising route to synchronizing spontaneous photon generation events and building scalable quantum networks.