Khurram K. Pirov scite author profile

At present, there are theoretical models of radio pulsar evolution which predict both the alignment, i.e., evolution of inclination angle χ between magnetic and rotational axes to 0 • , and its counter-alignment, i.e., evolution to 90 • . At the same time, both models well describe the pulsar distribution on P -Ṗ diagram. For this reason, up to now it was impossible to determine the braking mechanisms since it was rather difficult to estimate inclination angle evolution on the basis of observation. In this paper we demonstrate that statistics of interpulse pulsars can give us the key to solve alignment/counter-alignment problem as the number of interpulse pulsars (both, having χ ∼ 0 • and χ ∼ 90 • ) drastically depends on evolution of inclination angle.

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Entangled resource for interfacing single- and dual-rail optical qubits

Drahi

Sychev

Pirov

et al. 2021

Quantum

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Today's most widely used method of encoding quantum information in optical qubits is the dual-rail basis, often carried out through the polarisation of a single photon. On the other hand, many stationary carriers of quantum information – such as atoms – couple to light via the single-rail encoding in which the qubit is encoded in the number of photons. As such, interconversion between the two encodings is paramount in order to achieve cohesive quantum networks. In this paper, we demonstrate this by generating an entangled resource between the two encodings and using it to teleport a dual-rail qubit onto its single-rail counterpart. This work completes the set of tools necessary for the interconversion between the three primary encodings of the qubit in the optical field: single-rail, dual-rail and continuous-variable.

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Entanglement of macroscopically distinct states of light

Sychev¹,

Novikov²,

Pirov³

et al. 2019

Optica

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Schrödinger's famous Gedankenexperiment has inspired multiple generations of physicists to think about apparent paradoxes that arise when the logic of quantum physics is applied to macroscopic objects. The development of quantum technologies enabled us to produce physical analogues of Schrödinger's cats, such as superpositions of macroscopically distinct states as well as entangled states of microscopic and macroscopic entities. Here we take one step further and prepare an optical state which, in Schrödinger's language, is equivalent to a superposition of two cats, one of which is dead and the other alive, but it is not known in which state each individual cat is. Specifically, the alive and dead states are, respectively, the displaced single photon and displaced vacuum (coherent state), with the magnitude of displacement being on a scale of 10 8 photons. These two states have significantly different photon statistics and are therefore macroscopically distinguishable.

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Entanglement of macroscopically distinct states of light

Sychev¹,

Novikov²,

Pirov³

et al. 2018

Preprint

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Khurram K. Pirov

Statistics of interpulse radio pulsars: the key to solving the alignment/counter-alignment problem

Entangled resource for interfacing single- and dual-rail optical qubits

Entanglement of macroscopically distinct states of light

Entanglement of macroscopically distinct states of light

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