Photonic-reconfigurable entanglement distribution network based on silicon quantum photonics

The entanglement distribution network connects remote users by sharing entanglement resources, which is essential for realizing quantum internet. We propose a photonic-reconfigurable entanglement distribution network (PR-EDN) based on a silicon quantum photonic chip. The entanglement resources are generated by a quantum light source array based on spontaneous four-wave mixing in silicon waveguides and distributed to different users through time-reversed Hong-Ou-Mandel interference by on-chip Mach-Zehnder interferometers with thermo-optic phase shifters (TOPSs). A chip sample is designed and fabricated, supporting a PR-EDN with 3 subnets and 24 users. The network topology of the PR-EDN could be reconfigured in three network states by controlling the quantum interference through the TOPSs, which is demonstrated experimentally. Furthermore, a reconfigurable entanglement-based quantum key distribution network is realized as an application of the PR-EDN. The reconfigurable network topology makes the PR-EDN suitable for future quantum networks requiring complicated network control and management. Moreover, it is also shown that silicon quantum photonic chips have great potential for large-scale PR-EDN, thanks to their capacities for generating and manipulating plenty of entanglement resources.& COPY; 2023 Chinese Laser Press

Automated summary

This research proposes a photonic-reconfigurable entanglement distribution network (PR-EDN) based on a silicon quantum photonic chip, which is crucial for realizing quantum internet. The entanglement resources are generated by a quantum light source array based on spontaneous four-wave mixing in silicon waveguides and distributed to different users through on-chip Mach-Zehnder interferometers with thermo-optic phase shifters. Experimental demonstrations show that the network topology of the PR-EDN can be reconfigured in three states by controlling the quantum interference through the phase shifters. In addition, a reconfigurable entanglement-based quantum key distribution network is realized as an application of the PR-EDN, which makes it suitable for future quantum networks requiring complex network control and management. Moreover, silicon quantum photonic chips show great potential for large-scale PR-EDN due to their capabilities for generating and manipulating plenty of entanglement resources.