Long-distance entanglement generation in two-dimensional networks

Dorner, U.; Jaksch, Dieter

doi:10.1103/physreva.82.042326

Cited by 7 publications

(9 citation statements)

References 35 publications

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“…Protocols on networks using this approach were studied in [24,25]. This work was extended to a hybrid approach addressing both the first and second question in [81]. The protocols presented in these three articles are the subject of this subsection.…”

Section: Towards Noisy Quantum Networkmentioning

confidence: 99%

“…In the case where the parameters are different within a link, we must first do a PCM, which maps the problem to the original pure-state percolation problem with some of the links probabilistically deleted. A similar idea is used in [81], where pairs in certain rank-three states replace the PMSs. These can be converted to binary states via a sort of PCM that leave a separable state on failure.…”

Section: Towards Noisy Quantum Networkmentioning

confidence: 99%

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Distribution of entanglement in large-scale quantum networks

et al. 2013

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Abstract. The concentration and distribution of quantum entanglement is an essential ingredient in emerging quantum information technologies. Much theoretical and experimental effort has been expended in understanding how to distribute entanglement in one-dimensional networks. However, as experimental techniques in quantum communication develop, protocols for multi-dimensional systems become essential. Here, we focus on recent theoretical developments in protocols for distributing entanglement in regular and complex networks, with particular attention to percolation theory and network-based error correction.

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Section: Towards Noisy Quantum Networkmentioning

confidence: 99%

Section: Towards Noisy Quantum Networkmentioning

confidence: 99%

Distribution of entanglement in large-scale quantum networks

et al. 2013

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“…The probability η The function generating ξ(s, t) can be computed similar to Eqs. (12) and (14). In this case, it is a function of two variables: h ξ (x, y) = s,t≥0 ξ(s, t)y s x t .…”

Section: Discussionmentioning

confidence: 99%

“…In this case, a higher number of paths may exist which can help in the communication: with the existence of clusters of nodes connected by entangled states, two distant nodes will be able to establish entanglement between them if they both belong to the same cluster [4]. Entanglement percolation, which makes use of such higher dimensional networks, was first proposed in the honeycomb lattice [5] and later extended to other regular lattices [6,7], to schemes using multipartite entanglement [8] and to noisy networks [9][10][11][12]. In Ref.…”

Section: Introductionmentioning

confidence: 99%

Limited-path-length entanglement percolation in quantum complex networks

Cuquet¹,

Calsamiglia²

2011

Phys. Rev. A

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We study entanglement distribution in quantum complex networks where nodes are connected by bipartite entangled states. These networks are characterized by a complex structure, which dramatically affects how information is transmitted through them. For pure quantum state links, quantum networks exhibit a remarkable feature absent in classical networks: it is possible to effectively rewire the network by performing local operations on the nodes. We propose a family of such quantum operations that decrease the entanglement percolation threshold of the network and increase the size of the giant connected component. We provide analytic results for complex networks with arbitrary (uncorrelated) degree distribution. These results are in good agreement with numerical simulations, which also show enhancement in correlated and real world networks. The proposed quantum preprocessing strategies are not robust in the presence of noise. However, even when the links consist of (noisy) mixed state links, one can send quantum information through a connecting path with a fidelity that decreases with the path length. In this noisy scenario, complex networks offer a clear advantage over regular lattices, namely the fact that two arbitrary nodes can be connected through a relatively small number of steps, known as the small world effect. We calculate the probability that two arbitrary nodes in the network can successfully communicate with a fidelity above a given threshold. This amounts to working out the classical problem of percolation with limited path length. We find that this probability can be significant even for paths limited to few connections, and that the results for standard (unlimited) percolation are soon recovered if the path length exceeds by a finite amount the average path length, which in complex networks generally scales logarithmically with the size of the network.

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“…Much of the recent research in the quantum information field has focused on developing new techniques to engineer long-distance entanglement [1][2][3][4] and to obtain high-fidelity communication between distant parties [5][6][7][8]. Mastery of these techniques represents a crucial step toward the practical implementation of quantum computing and communication protocols, and developments have been witnessed within both bosonic and fermionic systems.…”

Section: Introductionmentioning

confidence: 99%

Nonlocal dissipative tunneling for high-fidelity quantum-state transfer between distant parties

Ponte

Moussa

2012

Phys. Rev. A

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In this work, we propose the nonlocal tunneling mechanism for high-fidelity state transfer between distant parties. The nonlocal tunneling follows from the overlap between the distant sending and receiving wave functions, which is indirectlymediated by the off-resonant normal modes of a quantum channel. This channel is made up of a network of dissipative quantum systems exhibiting the same bosonic or fermionic statistical nature as the sender and receiver. We demonstrate that the incoherence arising from quantum channel nonidealities is almost completely circumvented by the tunneling mechanism, which thus affords a high-fidelity transfer process.

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Long-distance entanglement generation in two-dimensional networks

Cited by 7 publications

References 35 publications

Distribution of entanglement in large-scale quantum networks

Distribution of entanglement in large-scale quantum networks

Limited-path-length entanglement percolation in quantum complex networks

Nonlocal dissipative tunneling for high-fidelity quantum-state transfer between distant parties

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