Enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing

Fiber designs that can that can keep up with increasing data demands are lacking. Here, the authors describe an interaction between the spin and orbital angular momenta of light which enables propagation of 24 states in a single optical fiber with low cross-talk, even in the presence of fiber pertur...

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Autores principales: P. Gregg, P. Kristensen, A. Rubano, S. Golowich, L. Marrucci, S. Ramachandran
Formato: article
Lenguaje:EN
Publicado: Nature Portfolio 2019
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Acceso en línea:https://doaj.org/article/e257ec12fe8e4c08bee318647c9bbc00
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spelling oai:doaj.org-article:e257ec12fe8e4c08bee318647c9bbc002021-12-02T14:38:58ZEnhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing10.1038/s41467-019-12401-42041-1723https://doaj.org/article/e257ec12fe8e4c08bee318647c9bbc002019-10-01T00:00:00Zhttps://doi.org/10.1038/s41467-019-12401-4https://doaj.org/toc/2041-1723Fiber designs that can that can keep up with increasing data demands are lacking. Here, the authors describe an interaction between the spin and orbital angular momenta of light which enables propagation of 24 states in a single optical fiber with low cross-talk, even in the presence of fiber perturbation.P. GreggP. KristensenA. RubanoS. GolowichL. MarrucciS. RamachandranNature PortfolioarticleScienceQENNature Communications, Vol 10, Iss 1, Pp 1-8 (2019)
institution DOAJ
collection DOAJ
language EN
topic Science
Q
spellingShingle Science
Q
P. Gregg
P. Kristensen
A. Rubano
S. Golowich
L. Marrucci
S. Ramachandran
Enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing
description Fiber designs that can that can keep up with increasing data demands are lacking. Here, the authors describe an interaction between the spin and orbital angular momenta of light which enables propagation of 24 states in a single optical fiber with low cross-talk, even in the presence of fiber perturbation.
format article
author P. Gregg
P. Kristensen
A. Rubano
S. Golowich
L. Marrucci
S. Ramachandran
author_facet P. Gregg
P. Kristensen
A. Rubano
S. Golowich
L. Marrucci
S. Ramachandran
author_sort P. Gregg
title Enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing
title_short Enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing
title_full Enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing
title_fullStr Enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing
title_full_unstemmed Enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing
title_sort enhanced spin orbit interaction of light in highly confining optical fibers for mode division multiplexing
publisher Nature Portfolio
publishDate 2019
url https://doaj.org/article/e257ec12fe8e4c08bee318647c9bbc00
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AT pkristensen enhancedspinorbitinteractionoflightinhighlyconfiningopticalfibersformodedivisionmultiplexing
AT arubano enhancedspinorbitinteractionoflightinhighlyconfiningopticalfibersformodedivisionmultiplexing
AT sgolowich enhancedspinorbitinteractionoflightinhighlyconfiningopticalfibersformodedivisionmultiplexing
AT lmarrucci enhancedspinorbitinteractionoflightinhighlyconfiningopticalfibersformodedivisionmultiplexing
AT sramachandran enhancedspinorbitinteractionoflightinhighlyconfiningopticalfibersformodedivisionmultiplexing
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