Paper detail

Storing High-Dimensional Quantum States in a Cold Atomic Ensemble

The reversible transfer of the quantum information between a photon, an information carrier, and a quantum memory with high fidelity and reliability is the prerequisite for realizing a long-distance quantum communication and a quantum network. Encoding photons into higher-dimensional states could significantly increase their information-carrying capability and network capacity. Moreover, the large-alphabet quantum key distribution affords a more secure flux of information. Quantum memories have been realized in different physical systems, such as atomic ensembles and solid systems etc., but to date, all quantum memories only realize the storage and retrieval of the photons lived in a two-dimensional space spanned for example by orthogonal polarizations, therefore only a quantum bit could be stored there. Here, we report on the first experimental realization of a quantum memory storing a photon lived in a three-dimensional space spanned by orbital angular momentums via electromagnetically induced transparency in a cold atomic ensemble. We reconstruct the storage process density matrix with the fidelity of 85.3% by the aid of a 4-f imaging system experimentally. The ability to store a high-dimensional quantum state with high fidelity is very promising for building a high-dimensional quantum network.