Photonic quantum state transfer between a cold atomic gas and a crystal

TL;DR

This paper demonstrates the first optical quantum state transfer between a cold atomic ensemble and a rare-earth doped crystal, enabling heterogeneous quantum networks through photon storage and frequency conversion.

Contribution

It introduces a novel hybrid quantum interface that faithfully transfers quantum states between two fundamentally different matter systems using cascaded quantum frequency conversion.

Findings

Quantum correlations transferred between atomic ensemble and crystal.

Single-photon time-bin qubits stored and retrieved with >85% fidelity.

First demonstration of optical quantum interconnection between disparate matter systems.

Abstract

Interfacing fundamentally different quantum systems is key to build future hybrid quantum networks. Such heterogeneous networks offer superior capabilities compared to their homogeneous counterparts as they merge individual advantages of disparate quantum nodes in a single network architecture. However, only very few investigations on optical hybrid-interconnections have been carried out due to the high fundamental and technological challenges, which involve e.g. wavelength and bandwidth matching of the interfacing photons. Here we report the first optical quantum interconnection between two disparate matter quantum systems with photon storage capabilities. We show that a quantum state can be faithfully transferred between a cold atomic ensemble and a rare-earth doped crystal via a single photon at telecommunication wavelength, using cascaded quantum frequency conversion. We first demonstrate that quantum correlations between a photon and a single collective spin excitation in the cold atomic ensemble can be transferred onto the solid-state system. We also show that single-photon time-bin qubits generated in the cold atomic ensemble can be converted, stored and retrieved from the crystal with a conditional qubit fidelity of more than $85\%$. Our results open prospects to optically connect quantum nodes with different capabilities and represent an important step towards the realization of large-scale hybrid quantum networks.