Squeezing-enhanced quantum key distribution over atmospheric channels

Derkach, Ivan; Usenko, Vladyslav C.; Filip, Radim

doi:10.1088/1367-2630/ab7f8f

Cited by 31 publications

(16 citation statements)

References 61 publications

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“…These tests, along with the numerical modeling, confirm the feasibility of quantum key distribution with macroscopically bright (intense and multimode) coherent states, which can be now fully implemented in real optical channels. Indeed, we show that key rates of about 0.25 bits per channel should be achievable with the states containing 10 4 photons at attenuation of 50%, which corresponds to a few kilometers long atmospheric link [33][34][35] (or 15 kilometers of a telecom fiber) and at local oscillator brightness of 10 6 photons, so that the key rate is only 15% reduced compared to the standard quantum key distribution with low-energy signals. In addition to increasing the LO brightness, the trusted parties can suppress the noise, concerned with the mode mismatch, by increasing the number of matched modes, which shows the potential of multiplexed continuous-variable quantum key distribution even in the case of join measurement of the multiple signal modes.…”

Section: Resultsmentioning

confidence: 92%

“…The results are given in Fig. 5 versus the LO brightness, as set in the experiment (left panel) and versus total signal beam brightness at the maximum reached LO brightness of 10 6 photons (right) at T = 0.5, which would correspond to a few kilometers long free-space channel [33][34][35] (or cca. 15 kilometers of the telecom fiber with attenuation of −0.2 dB/km).…”

Section: Qkd With Bright Multimode Coherent States and Mode Mismatchmentioning

confidence: 99%

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Feasibility of quantum key distribution with macroscopically bright coherent light

et al. 2019

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We address feasibility of continuous-variable quantum key distribution using bright multimode coherent states of light and homodyne detection. We experimentally verify the possibility to properly select signal modes by matching them with the local oscillator and this way to decrease the quadrature noise concerned with unmatched bright modes. We apply the results to theoretically predict the performance of continuous-variable quantum key distribution scheme using multimode coherent states in scenarios where modulation is applied either to all the modes or only to the matched ones, and confirm that the protocol is feasible at high overall brightness. Our results open the pathway towards full-scale implementation of quantum key distribution using bright light, thus bringing quantum communication closer to classical optics.

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Section: Resultsmentioning

confidence: 92%

Section: Qkd With Bright Multimode Coherent States and Mode Mismatchmentioning

confidence: 99%

Feasibility of quantum key distribution with macroscopically bright coherent light

et al. 2019

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“…In this regime, security can be established for every LEO satellite altitude and feasible squeezing

(SNU) provides a noticeable rate gain. Note that under the individual attacks, the higher levels of squeezing always translate into a higher secure key rate, which is not the case for collective attacks where the transmittance fluctuations limit the applicable values of squeezing [ 66 ] and require active squeezing optimization based on the estimated atmospheric transmittance distribution. The optimization of the latter is a crucial step required for the establishing of secure key rate based on the data generated from a single pass of the satellite.…”

Section: CV Qkd Over Satellite Channelsmentioning

confidence: 99%

Applicability of Squeezed- and Coherent-State Continuous-Variable Quantum Key Distribution over Satellite Links

Derkach

Usenko

2020

Entropy

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We address the applicability of quantum key distribution with continuous-variable coherent and squeezed states over long-distance satellite-based links, considering low Earth orbits and taking into account strong varying channel attenuation, atmospheric turbulence and finite data ensemble size effects. We obtain tight security bounds on the untrusted excess noise on the channel output, which suggest that substantial efforts aimed at setup stabilization and reduction of noise and loss are required, or the protocols can be realistically implemented over satellite links once either individual or passive collective attacks are assumed. Furthermore, splitting the satellite pass into discrete segments and extracting the key from each rather than from the overall single pass allows one to effectively improve robustness against the untrusted channel noise and establish a secure key under active collective attacks. We show that feasible amounts of optimized signal squeezing can substantially improve the applicability of the protocols allowing for lower system clock rates and aperture sizes and resulting in higher robustness against channel attenuation and noise compared to the coherent-state protocol.

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“…Therefore, if the channel is heavily fluctuating, then Var ( √ T ) and the respective effective excess noise will be large, which results in a low key rate or could even lead to a security break [35]. This can be partially compensated by the use of squeezed states [7] or by stabilizing the channel [36].…”

Section: The Effect Of Fluctuationsmentioning

confidence: 99%

Fading channel estimation for free-space continuous-variable secure quantum communication

et al. 2019

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We investigate estimation of fluctuating channels and its effect on security of continuous-variable quantum key distribution. We propose a novel estimation scheme which is based on the clusterization of the estimated transmittance data. We show that uncertainty about whether the transmittance is fixed or not results in a lower key rate. However, if the total number of measurements is large, one can obtain using our method a key rate similar to the non-fluctuating channel even for highly fluctuating channels. We also verify our theoretical assumptions using experimental data from an atmospheric quantum channel. Our method is therefore promising for secure quantum communication over strongly fluctuating turbulent atmospheric channels.

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Squeezing-enhanced quantum key distribution over atmospheric channels

Cited by 31 publications

References 61 publications

Feasibility of quantum key distribution with macroscopically bright coherent light

Feasibility of quantum key distribution with macroscopically bright coherent light

Applicability of Squeezed- and Coherent-State Continuous-Variable Quantum Key Distribution over Satellite Links

Fading channel estimation for free-space continuous-variable secure quantum communication

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