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Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures

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Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures. / Artemyev, Yuriy A.; Savinov, V.; Katiyi, Aviad et al.
In: Nanoscale Advances, Vol. 3, No. 1, 07.01.2021, p. 190-197.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Artemyev, YA, Savinov, V, Katiyi, A, Shalin, AS & Karabchevsky, A 2021, 'Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures', Nanoscale Advances, vol. 3, no. 1, pp. 190-197. https://doi.org/10.1039/d0na00580k

APA

Artemyev, Y. A., Savinov, V., Katiyi, A., Shalin, A. S., & Karabchevsky, A. (2021). Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures. Nanoscale Advances, 3(1), 190-197. https://doi.org/10.1039/d0na00580k

Vancouver

Artemyev YA, Savinov V, Katiyi A, Shalin AS, Karabchevsky A. Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures. Nanoscale Advances. 2021 Jan 7;3(1):190-197. doi: 10.1039/d0na00580k

Author

Artemyev, Yuriy A. ; Savinov, V. ; Katiyi, Aviad et al. / Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures. In: Nanoscale Advances. 2021 ; Vol. 3, No. 1. pp. 190-197.

Bibtex

@article{f10340189b0e4fb69dc01f3bec973811,
title = "Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures",
abstract = "The creation of single photon sources on a chip is a mid-term milestone on the road to chip-scale quantum computing. An in-depth understanding of the extended multipole decomposition of non-isolated sources of electromagnetic radiation is not only relevant for a microscopic description of fundamental phenomena, such as light propagation in a medium, but also for emerging applications such as single-photon sources. To design single photon emitters on a chip, we consider a ridge dielectric waveguide perturbed with a cylindrical inclusion. For this, we expanded classical multipole decomposition that allows simplifying and interpreting complex optical interactions in an intuitive manner to make it suitable for analyzing light-matter interactions with non-isolated objects that are parts of a larger network, e.g. individual components such as a single photon source of an optical chip. It is shown that our formalism can be used to design single photon sources on a chip. ",
author = "Artemyev, {Yuriy A.} and V. Savinov and Aviad Katiyi and Shalin, {Alexander S.} and Alina Karabchevsky",
year = "2021",
month = jan,
day = "7",
doi = "10.1039/d0na00580k",
language = "English",
volume = "3",
pages = "190--197",
journal = "Nanoscale Advances",
issn = "2516-0230",
publisher = "Royal Society of Chemistry",
number = "1",

}

RIS

TY - JOUR

T1 - Non-isolated sources of electromagnetic radiation by multipole decomposition for photonic quantum technologies on a chip with nanoscale apertures

AU - Artemyev, Yuriy A.

AU - Savinov, V.

AU - Katiyi, Aviad

AU - Shalin, Alexander S.

AU - Karabchevsky, Alina

PY - 2021/1/7

Y1 - 2021/1/7

N2 - The creation of single photon sources on a chip is a mid-term milestone on the road to chip-scale quantum computing. An in-depth understanding of the extended multipole decomposition of non-isolated sources of electromagnetic radiation is not only relevant for a microscopic description of fundamental phenomena, such as light propagation in a medium, but also for emerging applications such as single-photon sources. To design single photon emitters on a chip, we consider a ridge dielectric waveguide perturbed with a cylindrical inclusion. For this, we expanded classical multipole decomposition that allows simplifying and interpreting complex optical interactions in an intuitive manner to make it suitable for analyzing light-matter interactions with non-isolated objects that are parts of a larger network, e.g. individual components such as a single photon source of an optical chip. It is shown that our formalism can be used to design single photon sources on a chip.

AB - The creation of single photon sources on a chip is a mid-term milestone on the road to chip-scale quantum computing. An in-depth understanding of the extended multipole decomposition of non-isolated sources of electromagnetic radiation is not only relevant for a microscopic description of fundamental phenomena, such as light propagation in a medium, but also for emerging applications such as single-photon sources. To design single photon emitters on a chip, we consider a ridge dielectric waveguide perturbed with a cylindrical inclusion. For this, we expanded classical multipole decomposition that allows simplifying and interpreting complex optical interactions in an intuitive manner to make it suitable for analyzing light-matter interactions with non-isolated objects that are parts of a larger network, e.g. individual components such as a single photon source of an optical chip. It is shown that our formalism can be used to design single photon sources on a chip.

U2 - 10.1039/d0na00580k

DO - 10.1039/d0na00580k

M3 - Journal article

C2 - 36131865

VL - 3

SP - 190

EP - 197

JO - Nanoscale Advances

JF - Nanoscale Advances

SN - 2516-0230

IS - 1

ER -