All-Optical Hyperentangled Photonic Quantum Memory

Quantum optical memories are a key component to a variety of quantum information applications, from extending quantum communication channels to building high-efficiency single-photon sources to enabling protocols requiring multiple synchronized qubits. However, most current photon storage systems utilize light-matter interactions and are therefore not broadband; meanwhile the available broader-bandwidth photon storage systems operate with somewhat shorter storage times or require cryogenic operation. Here we develop a system with multiplexed free-space storage cavities, able to store single photons with high efficiency over variable delays, up to 12.5 µs, and over several nanometers bandwidth at room temperature. The system can store multiple qubits encoded in various degrees of freedom (e.g., spatial modes, time-bin, and polarization) simultaneously. This work has demonstrated storage of polarization states for 1.25 µs and retrieval through single-mode fiber with a state fidelity >99% and efficiency ~82%. A future goal for this experiment is to achieve storage of hyperentangled qubits, while also extending the storage time to ~100 µs by improving the optics used.