Beating direct transmission bounds for quantum key distribution with a multiple quantum memory station

Trényi, Róbert; Lütkenhaus, Norbert

doi:10.1103/physreva.101.012325

Cited by 15 publications

(18 citation statements)

References 45 publications

(79 reference statements)

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“…To this end, we have developed a large scale numerical Monte Carlo simulation for quantum repeaters that can faithfully represent loss and imperfect quantum memories, as well as other sources of noise such as dark counts. While there are existing approaches dealing with the computation of key rates for different repeater setups [4,25,26,32], the generalization of these methods to longer distances and other error models is by no means straightforward, e.g. an analytical approach also involves an intricate analysis of entanglement swapping strategies [33].…”

Section: Resultsmentioning

confidence: 99%

“…The main difference from protocols in Refs. [25,26] is that the satellites with entangled pair sources do not have the information about whether a qubit has been loaded into memory successfully. Therefore, it makes sense for the source not to wait until confirmation from the satellite with the memory but to instead continuously send out entangled pairs.…”

Section: A Scenariomentioning

confidence: 99%

“…However, untrusted node operation for beyond-line-of-sight distances towards truly global scales requires the implementation of a QR protocol enabled by on-board quantum memories (QMs) [21,22]. Furthermore, QMs do not only help increase the overall network range but also offer a solution to low detection rates in entanglement-based schemes [23][24][25][26][27][28] and thus facilitate memory-assisted QKD (MA-QKD) protocols which can be thought of as a single-node QR link. By synchronizing otherwise probabilistic detections, a single repeater station with a QM would change the scaling of the key rate from η ch to √ η ch where η ch is the channel transmission.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Simulating quantum repeater strategies for multiple satellites

Wallnöfer,

Hahn,

Gündoğan

et al. 2021

Preprint

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A global quantum repeater network involving satellite-based links is likely to have advantages over fiberbased networks in terms of long-distance communication, since the photon losses in free space scale only polynomially with the distance -compared to the exponential losses in optical fibers. To simulate the performance of such networks, we have introduced a scheme of large-scale event-based Monte Carlo simulation of quantum repeaters with multiple memories that can faithfully represent loss and imperfections in these memories. In this work, we identify the quantum key distribution rates achievable in various satellite and ground station geometries for feasible experimental parameters. The power and flexibility of the simulation toolbox allows us to explore various strategies and parameters, some of which only arise in these more complex, multi-satellite repeater scenarios. As a primary result, we conclude that key rates in the kHz range are reasonably attainable for intercontinental quantum communication with three satellites, only one of which carries a quantum memory.

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Section: Resultsmentioning

confidence: 99%

Section: A Scenariomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Simulating quantum repeater strategies for multiple satellites

Wallnöfer,

Hahn,

Gündoğan

et al. 2021

Preprint

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show abstract

“…no QM (grey dashed) 42 ; (ii) uplink configuration with protocol presented in ref. 31,32 (blue) and finally (iii) downlink scenario with a single memory pair (m = 1, red) and 100 memory pairs (m = 100, green) 43 . Parameters used in simulations to generate Figs.…”

Section: Quantum Repeatersmentioning

confidence: 99%

“…This also requires long-lived QMs with storage times in the order of seconds to achieve similar performance to the previous method. An extension of this protocol in which the central pair of QMs are replaced with m pairs of QMs 43 reduces the required storage time.…”

Section: Quantum Repeatersmentioning

confidence: 99%

Proposal for space-borne quantum memories for global quantum networking

et al. 2021

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Global-scale quantum communication links will form the backbone of the quantum internet. However, exponential loss in optical fibres precludes any realistic application beyond few hundred kilometres. Quantum repeaters and space-based systems offer solutions to overcome this limitation. Here, we analyse the use of quantum memory (QM)-equipped satellites for quantum communication focussing on global range repeaters and memory-assisted (MA-) QKD, where QMs help increase the key rate by synchronising otherwise probabilistic detection events. We demonstrate that satellites equipped with QMs provide three orders of magnitude faster entanglement distribution rates than existing protocols based on fibre-based repeaters or space systems without QMs. We analyse how entanglement distribution performance depends on memory characteristics, determine benchmarks to assess the performance of different tasks and propose various architectures for light-matter interfaces. Our work provides a roadmap to realise unconditionally secure quantum communications over global distances with near-term technologies.

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A quantum router architecture for high-fidelity entanglement flows in quantum networks

et al. 2022

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The past decade has seen tremendous progress in experimentally realizing the building blocks of quantum repeaters. Repeater architectures with multiplexed quantum memories have been proposed to increase entanglement distribution rates, but an open challenge is to maintain entanglement fidelity over long-distance links. Here, we address this with a quantum router architecture comprising many quantum memories connected in a photonic switchboard to broker entanglement flows across quantum networks. We compute the rate and fidelity of entanglement distribution under this architecture using an event-based simulator, finding that the router improves the entanglement fidelity as multiplexing depth increases without a significant drop in the entanglement distribution rate. Specifically, the router permits channel-loss-invariant fidelity, i.e. the same fidelity achievable with lossless links. Furthermore, this scheme automatically prioritizes entanglement flows across the full network without requiring global network information. The proposed architecture uses present-day photonic technology, opening a path to near-term deployable multi-node quantum networks.

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Beating direct transmission bounds for quantum key distribution with a multiple quantum memory station

Cited by 15 publications

References 45 publications

Simulating quantum repeater strategies for multiple satellites

Simulating quantum repeater strategies for multiple satellites

Proposal for space-borne quantum memories for global quantum networking

A quantum router architecture for high-fidelity entanglement flows in quantum networks

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