Abstract
We consider the problem of generating multipartite entangled states in a quantum network upon request. We follow a top-down approach, where the required entanglement is initially present in the network in form of network states shared between network devices, and then manipulated in such a way that the desired target state is generated. This minimizes generation times, and allows for network structures that are in principle independent of physical links. We present a modular and flexible architecture, where a multi-layer network consists of devices of varying complexity, including quantum network routers, switches and clients, that share certain resource states. We concentrate on the generation of graph states among clients, which are resources for numerous distributed quantum tasks. We assume minimal functionality for clients, i.e. they do not participate in the complex and distributed generation process of the target state. We present architectures based on shared multipartite entangled Greenberger–Horne–Zeilinger states of different size, and fully connected decorated graph states, respectively. We compare the features of these architectures to an approach that is based on bipartite entanglement, and identify advantages of the multipartite approach in terms of memory requirements and complexity of state manipulation. The architectures can handle parallel requests, and are designed in such a way that the network state can be dynamically extended if new clients or devices join the network. For generation or dynamical extension of the network states, we propose a quantum network configuration protocol, where entanglement purification is used to establish high fidelity states. The latter also allows one to show that the entanglement generated among clients is private, i.e. the network is secure.
Highlights
Quantum communication is an emerging discipline within quantum information science
Since ci clients connect to network device i we find that the total number of Bell-pairs necessary to establish the full network state is given by m−1 m ci cj
We have presented elementary buildings blocks at an abstract level for quantum networks which enable the generation of arbitrary graph states in a highly distributed manner
Summary
Quantum communication is an emerging discipline within quantum information science. The applications of quantum communication range from quantum key distribution [1,2,3,4,5] over secure quantum channels [6,7,8] to distributed quantum computation [9] or quantum key agreement protocols [10,11,12]. The time to generate the requested state only amounts to classical communication between devices, since all required measurements and operations can be done in a single time step In such an entanglement-based approach, the network structure is at this stage in principle independent of the physical links. The focus of quantum networks relying on our architectures lies on describing a straightforward way to distribute arbitrary graph states in the network and providing fast response times for its clients This is not necessarily the most resource efficient way and if the state requested by the clients is known beforehand or the set of target states of the network is restricted, it would certainly be possible to develop optimized architectures for those applications. To establish states with high fidelity among the devices, we rely on encoded transmission using quantum error correction, or bipartite and multipartite repeater architectures Both approaches allow one in principle to establish long-distance entanglement in a network. XI where we provide an outlook and identify interesting open questions
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