2017
DOI: 10.1103/physrevlett.119.240403
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Quantum Experiments and Graphs: Multiparty States as Coherent Superpositions of Perfect Matchings

Abstract: We show a surprising link between experimental setups to realize high-dimensional multipartite quantum states and Graph Theory. In these setups, the paths of photons are identified such that the photon-source information is never created. We find that each of these setups corresponds to an undirected graph, and every undirected graph corresponds to an experimental setup. Every term in the emerging quantum superposition corresponds to a perfect matching in the graph. Calculating the final quantum state is in th… Show more

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Cited by 91 publications
(102 citation statements)
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“…Using a recently uncovered bridge between quantum experiments with probabilistic photon pair sources and graph theory [13], we answer this question for many classes of entangled states. The correspondence is listed in Table I.…”
mentioning
confidence: 99%
See 1 more Smart Citation
“…Using a recently uncovered bridge between quantum experiments with probabilistic photon pair sources and graph theory [13], we answer this question for many classes of entangled states. The correspondence is listed in Table I.…”
mentioning
confidence: 99%
“…In this paper, we briefly summarize the main results from [13] and explain the connection between quantum experiments and graphs. Then we show graphs and experimental setups for creating 2-dimensional and 3-dimensional GHZ states as well as 4-particle W state.…”
mentioning
confidence: 99%
“…Interestingly, this indicates that the dimension of GHZ states grows when more crystals are added in the case of 3-photon sources. This is in stark contrast to the case of 2photon sources where the maximum dimension d = 3 [15,60,61]. If we restrict ourselves to two n-photon sources firing simultaneously, then the maximal possible dimension for a GHZ state grows as n = 2 − 7; d = 3, 10, 35, 126, 462, 1716, 6435, which is potentially connected to the integer sequence in OEIS A001700 [62] (number of ways to put n + 1 indistinguishable balls into n + 1 distinguishable boxes).…”
Section: Bs2mentioning
confidence: 67%
“…Those photon pairs are then interpreted as two vertices connected by an edge. This simple idea has been exploited in [15][16][17] to understand better the generalization of quantum states, quantum information protocols and for gaining new insights towards quantum computation.…”
Section: Introductionmentioning
confidence: 99%
“…These authors used four paths to prepare two entangled photon‐pair sources and subsequently arbitrarily regulated these sources to construct various four‐photon graph states. By further reducing the loss and increasing the rates, we can display more complex graph state construction with more photon numbers directly on the silicon chip …”
Section: Multiphoton State Preparationmentioning
confidence: 99%