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

Research output: Contribution to journalJournal articleResearchpeer-review

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Entangled resource for interfacing single- and dual-rail optical qubits. / Drahi, David; Sychev, Demid; Pirov, Khurram K.; Sazhina, Ekaterina A.; Novikov, Valeriy A.; Walmsley, Ian A.; Lvovsky, A.

In: Quantum, Vol. 5, 416, 23.03.2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Drahi, D, Sychev, D, Pirov, KK, Sazhina, EA, Novikov, VA, Walmsley, IA & Lvovsky, A 2021, 'Entangled resource for interfacing single- and dual-rail optical qubits', Quantum, vol. 5, 416. https://doi.org/10.22331/q-2021-03-23-416

APA

Drahi, D., Sychev, D., Pirov, K. K., Sazhina, E. A., Novikov, V. A., Walmsley, I. A., & Lvovsky, A. (2021). Entangled resource for interfacing single- and dual-rail optical qubits. Quantum, 5, [416]. https://doi.org/10.22331/q-2021-03-23-416

Vancouver

Drahi D, Sychev D, Pirov KK, Sazhina EA, Novikov VA, Walmsley IA et al. Entangled resource for interfacing single- and dual-rail optical qubits. Quantum. 2021 Mar 23;5. 416. https://doi.org/10.22331/q-2021-03-23-416

Author

Drahi, David ; Sychev, Demid ; Pirov, Khurram K. ; Sazhina, Ekaterina A. ; Novikov, Valeriy A. ; Walmsley, Ian A. ; Lvovsky, A. / Entangled resource for interfacing single- and dual-rail optical qubits. In: Quantum. 2021 ; Vol. 5.

Bibtex

@article{a939bf6441fa45aa9a7cfdbf78b7b5b2,
title = "Entangled resource for interfacing single- and dual-rail optical qubits",
abstract = "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 a qubit in the optical field: single-rail, dual-rail and continuous-variable.",
author = "David Drahi and Demid Sychev and Pirov, {Khurram K.} and Sazhina, {Ekaterina A.} and Novikov, {Valeriy A.} and Walmsley, {Ian A.} and A. Lvovsky",
year = "2021",
month = mar,
day = "23",
doi = "10.22331/q-2021-03-23-416",
language = "English",
volume = "5",
journal = "Quantum",
issn = "2521-327X",
publisher = "Verein zur F{\"o}rderung des Open Access Publizierens in den Quantenwissenschaften",

}

RIS

TY - JOUR

T1 - Entangled resource for interfacing single- and dual-rail optical qubits

AU - Drahi, David

AU - Sychev, Demid

AU - Pirov, Khurram K.

AU - Sazhina, Ekaterina A.

AU - Novikov, Valeriy A.

AU - Walmsley, Ian A.

AU - Lvovsky, A.

PY - 2021/3/23

Y1 - 2021/3/23

N2 - 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 a qubit in the optical field: single-rail, dual-rail and continuous-variable.

AB - 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 a qubit in the optical field: single-rail, dual-rail and continuous-variable.

U2 - 10.22331/q-2021-03-23-416

DO - 10.22331/q-2021-03-23-416

M3 - Journal article

VL - 5

JO - Quantum

JF - Quantum

SN - 2521-327X

M1 - 416

ER -

ID: 260589691