Entanglement-Enabled Connectivity Bounds for Quantum Networks
Abstract
In the Quantum Internet, multipartite entanglement enables a new form of network connectivity, referred to as artificial connectivity namely and able to augment the physical connectivity with artificial links between pairs of nodes, without any additional physical link deployment. In this paper, by engineering such an artificial connectivity, we theoretically determine upper and lower bounds for the number of EPR pairs and GHZ states that can be extracted among nodes that are not adjacent in the artificial network topology. The aforementioned analysis is crucial, since the extraction of EPR pairs and GHZ states among remote nodes constitutes the resource primitives for on-demand and end-to-end communications. Indeed, within the paper, we not only determine whether a certain number of remote EPR pairs and GHZ states can be extracted, but we also provide the locations, namely the identities, of the nodes interconnected by such entangled resources. Thus, our analysis is far from being purely theoretical, rather it is constructive, since we provide the sequence of operations required for performing such extractions.