Ramy Tannous scite author profile

Despite its widespread use in fiber optics, encoding quantum information in photonic time-bin states is usually considered impractical for free-space quantum communication as turbulence-induced spatial distortion impedes the analysis of time-bin states at the receiver. Here, we demonstrate quantum key distribution using time-bin photonic states distorted by turbulence and depolarization during free-space transmission. Utilizing a novel analyzer apparatus, we observe stable quantum bit error ratios of 5.32 %, suitable for generating secure keys, despite significant wavefront distortions and polarization fluctuations across a 1.2 km channel. This shows the viability of time-bin quantum communication over long-distance free-space channels, which will simplify direct fiber/free-space interfaces and enable new approaches for practical free-space quantum communication over multi-mode, turbulent, or depolarizing channels.

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Repeated radiation damage and thermal annealing of avalanche photodiodes

D’Souza

Bourgoin

Higgins

et al. 2021

EPJ Quantum Technol.

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Avalanche photodiodes (APDs) are well-suited for single-photon detection on quantum communication satellites as they are a mature technology with high detection efficiency without requiring cryogenic cooling. They are, however, prone to significantly increased thermal noise caused by in-orbit radiation damage. Previous work demonstrated that a one-time application of thermal annealing reduces radiation-damage-induced APD thermal noise. Here we examine the effect of cyclical proton irradiation and thermal annealing. We use an accelerated testing environment which emulates a realistic two-year operating profile of a satellite in low-Earth-orbit. We show that repeated thermal annealing is effective at maintaining thermal noise of silicon APDs within a range suitable for quantum key distribution throughout the nominal mission life, and beyond. We examine two strategies—annealing at a fixed period of time, and annealing only when the thermal noise exceeds a pre-defined limit. We find both strategies exhibit similar thermal noise at end-of-life, with a slight overall advantage to annealing conditionally. We also observe that afterpulsing probability of the detector increases with cumulative proton irradiation. This knowledge helps guide design and tasking decisions for future space-borne quantum communication applications.

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Demonstration of a 6 state-4 state reference frame independent channel for quantum key distribution

Tannous

Jin

et al. 2019

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We propose and demonstrate a novel protocol for reference frame independent quantum key distribution using six states for Alice and four states for Bob. We show that this protocol can generate a secure key for any possible phase of the entangled state, as long as the variation is small compared to the measurement run, despite the reduced four state measurement in Bob's polarization state analyzer. We perform a proof-of-principle experiment using polarization entangled photon pairs. Despite a rotational phase, we obtain a consistently low error rate of less than 3% indicating the feasibility of this protocol for quantum key distribution. Our protocol is beneficial but not limited to applications in satellite or mobile free-space QKD, where the remote communication node must limit resources and restrict the number of measured states to four instead of six.

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Demonstration of Reference Frame Independent Time Bin Quantum Key Distribution

Tannous

Wilson

Vinet

et al. 2022

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Sagnac-type entangled photon source using only conventional polarization optics

Lee

Xie

Tannous

et al. 2021

Quantum Sci. Technol.

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We designed and implemented a novel combination of a Sagnac-interferometer with a Mach–Zehnder interferometer for a source of polarization-entangled photons. The new versatile configuration does not require multi-wavelength polarization optics, yet it performs with a good polarization quality and phase-stability over a wide wavelength range. We demonstrate the interferometer using only standard commercial optics to experimentally realize the pulsed generation of polarization-entangled photon-pairs at wavelengths of 764 nm and 1221 nm via type-I spontaneous four-wave mixing in a polarization-maintaining fiber. Polarization entanglement was verified by a polarization-correlation measurement with a visibility of 95.5% from raw coincidence counts and the violation of the Clauser–Horne–Shimony–Holt (CHSH) inequality with S = 2.70 ± 0.04. The long-term phase-stability was characterized by an Allan deviation of 8° over an integration time of about 1 h with no active phase-stabilization.

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Ramy Tannous

Genuine time-bin-encoded quantum key distribution over a turbulent depolarizing free-space channel

Repeated radiation damage and thermal annealing of avalanche photodiodes

Demonstration of a 6 state-4 state reference frame independent channel for quantum key distribution

Demonstration of Reference Frame Independent Time Bin Quantum Key Distribution

Sagnac-type entangled photon source using only conventional polarization optics

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