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30 results on '"Burenkov, I. A."'

1. Metropolitan-scale Entanglement Distribution with Co-existing Quantum and Classical Signals in a single fiber

Author

Rahmouni, A., Kuo, P. S., Li-Baboud, Y. S., Burenkov, I. A., Shi, Y., Jabir, M. V., Lal, N., Reddy, D., Merzouki, M., Ma, L., Battou, A., Polyakov, S. V., Slattery, O., and Gerrits, T.

Subjects
Quantum Physics
Abstract

The development of prototype metropolitan-scale quantum networks is underway and entails transmitting quantum information via single photons through deployed optical fibers spanning several tens of kilometers. The major challenges in building metropolitan-scale quantum networks are compensation of polarization mode dispersion, high-precision clock synchronization, and compensation for cumulative transmission time fluctuations. One approach addressing these challenges is to co-propagate classical probe signals in the same fiber as the quantum signal. Thus, both signals experience the same conditions, and the changes of the fiber can therefore be monitored and compensated. Here, we demonstrate the distribution of polarization entangled quantum signals co-propagating with the White Rabbit Precision Time Protocol (WR-PTP) classical signals in the same single-core fiber strand at metropolitan-scale distances. Our results demonstrate the feasibility of this quantum-classical coexistence by achieving high-fidelity entanglement distribution between nodes separated by 100 km of optical fiber. This advancement is a significant step towards the practical implementation of robust and efficient metropolitan-scale quantum networks.

Published
2024
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3. Quantum receiver for large alphabet communication

Author

Burenkov, I. A., Tikhonova, O. V., and Polyakov, S. V.

Subjects
Quantum Physics
Abstract

Quantum mechanics allows measurements that surpass the fundamental sensitivity limits of classical methods. To benefit from the quantum advantage in a practical setting, the receiver should use communication channels resources optimally; this can be done employing large communication alphabets. Here we show the fundamental sensitivity potential of a quantum receiver for coherent communication with frequency shift keying. We introduce an adaptive quantum protocol for this receiver, show that its sensitivity outperforms other receivers for alphabet sizes above 4 and scales favorably, whereas quantum receivers explored to date suffer from degraded sensitivity with the alphabet size. In addition, we show that the quantum measurement advantage allows the much better use of the frequency space in comparison to classical frequency keying protocols and orthogonal frequency division multiplexing.

Published
2018
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4. Full statistical mode reconstruction of a light field via a photon-number resolved measurement

Author

Burenkov, I. A., Sharma, A. K., Gerrits, T., Harder, G., Bartley, T. J., Silberhorn, C., Goldschmidt, E. A., and Polyakov, S. V.

Subjects
Quantum Physics, Physics - Data Analysis, Statistics and Probability
Abstract

We present a method to reconstruct the complete statistical mode structure and optical losses of multimode conjugated optical fields using an experimentally measured joint photon-number probability distribution. We demonstrate that this method evaluates classical and non-classical properties using a single measurement technique and is well-suited for quantum mesoscopic state characterization. We obtain a nearly-perfect reconstruction of a field comprised of up to 10 modes based on a minimal set of assumptions. To show the utility of this method, we use it to reconstruct the mode structure of an unknown bright parametric down-conversion source., Comment: 7 pages, 3 figures

Published
2017
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6. Scalable, chip-based optically-controlled gates for quantum information processing

Author

Burenkov, I. A., Tikhonova, O. V., and Polyakov, S. V.

Subjects
Quantum Physics
Abstract

Here we present a simple and robust method to build on-the-fly configurable quantum gates based on a photonic exchange between quantum nodes. The idea is based on a high reflectivity of Bragg grating structures near resonant wavelengths. The control is exerted by applying an external strongly off-resonant or even a static electromagnetic field and taking advantage of the Kerr effect. When the nonlinear phase shift is strong enough, the Bragg mirror disappears, thereby allowing a transmission of a wave packet from one node to another. An example of a protocol for quantum logic gates that relies on this framework is offered., Comment: 8 pages, 5 figures

Published
2016
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8. 100-km entanglement distribution with coexisting quantum and classical signals in a single fiber

Author

Rahmouni, A., Kuo, P. S., Li-Baboud, Y. S., Burenkov, I. A., Shi, Y., Jabir, M. V., Lal, N., Reddy, D., Merzouki, M., Ma, L., Battou, A., Polyakov, S. V., Slattery, O., and Gerrits, T.

Abstract

The development of prototype metropolitan-scale quantum networks is underway and entails transmitting quantum information via single photons through deployed optical fibers spanning several tens of kilometers. The major challenges in building metropolitan-scale quantum networks are compensation for polarization fluctuation, high-precision clock synchronization, and compensation for cumulative transmission time fluctuations. One approach addressing these challenges is to copropagate classical probe signals in the same fiber as the quantum signal. Thus, both signals experience the same conditions, and the changes of the fiber can therefore be monitored and compensated. Here, we demonstrate the distribution of polarization-entangled quantum signals copropagating with the White Rabbit precision time protocol classical signals in the same single-core fiber strand at metropolitan-scale distances. Our results demonstrate the feasibility of this quantum-classical coexistence by achieving high-fidelity entanglement distribution between nodes separated by 100 km of optical fiber. This advancement is a significant step towards the practical implementation of robust and efficient metropolitan-scale quantum networks.

Published
2024
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10. Versatile quantum enabled telecom receiver

Author

Jabir M. V, Annafianto, N. F. R., Burenkov, I. A., Battou, A., and Polyakov, S. V.

Abstract

We demonstrate a time-resolving quantum receiver at a telecom wavelength. We show state discrimination errors below the shot noise limit for legacy, novel telecommunication protocols with long alphabets.

Published
2022
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25. Ionization of atoms and molecules by a few-cycle laser pulse and interference effects in the rescattering process.

Author

Burenkov, I. A., Popov, A. M., Tikhonova, O. V., and Volkova, E. A.

Subjects
*IONIZATION (Atomic physics), *MOLECULAR dynamics, *OPTICAL diffraction, *ULTRASHORT laser pulses, *QUANTUM interference, *QUANTUM theory
Abstract

We investigate the diffraction pictures arising due to strong-field ionization of a molecule in an ultrashort laser pulse and further field-induced recollision of the ionized electron with the parent molecular ion by direct numerical solution of the non-stationary Schrodinger equation. In molecules the angular distributions of the re-scattered electron are shown to differ dramatically from the simple usually used double-slit diffraction picture. The reason for this consists in the interference between scattered and non-scattered parts of the electron wave packet in the continuum. The found interference effect is demonstrated to play an important role in the formation of angular and momentum distribution both for molecules and atoms. [ABSTRACT FROM AUTHOR]

Published
2008
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26. White Rabbit-assisted quantum network node synchronization with quantum channel coexistence

Author

Gerrits, T., Burenkov, I. A., Li-Baboud, Y. S., Anouar Rahmouni, Anand, D. M., Hala, Slattery, O., Battou, A., and Polyakov, S. V.

Abstract

We show that the Ethernet-based time transfer protocol ‘White Rabbit’ can synchronize two distant quantum-networked nodes to within 4 ps, enabling HOM interference at >90 % visibility using 17.6 ps FWHM single-photons coexisting with White Rabbit.

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