Polymeric jets throw light on the origin and nature of the forest of solar spicules

Sahel Dey; Piyali Chatterjee; O. V.S.N. Murthy; Marianna B. Korsós; Jiajia Liu; Christopher J. Nelson; Robertus Erdélyi

doi:10.1038/s41567-022-01522-1

Polymeric jets throw light on the origin and nature of the forest of solar spicules

Sahel Dey
, Piyali Chatterjee^*
, O. V.S.N. Murthy
, Marianna B. Korsós
, Jiajia Liu
, Christopher J. Nelson
, Robertus Erdélyi

^*Awdur cyfatebol y gwaith hwn

Adran Ffiseg

Indian Institute of Astrophysics
Indian Institute of Soil Science
Azim Premji University
Eötvös Loránd University
Hungarian Science and Technology Foundation
University of Sheffield
Queen's University Belfast

Allbwn ymchwil: Cyfraniad at gyfnodolyn › Erthygl › adolygiad gan gymheiriaid

18 Dyfyniadau (Scopus)

Crynodeb

Spicules are plasma jets that are observed in the dynamic interface region between the visible solar surface and the hot corona. At any given time, it is estimated that about 3 million spicules are present on the Sun. We find an intriguing parallel between the simulated spicular forest in a solar-like atmosphere and the numerous jets of polymeric fluids when both are subjected to harmonic forcing. In a radiative magnetohydrodynamic numerical simulation with sub-surface convection, solar global surface oscillations are excited similarly to those harmonic vibrations. The jets thus produced match remarkably well with the forests of spicules detected in observations of the Sun. Taken together, the numerical simulations of the Sun and the laboratory fluid dynamics experiments provide insights into the mechanism underlying the ubiquity of jets. The non-linear focusing of quasi-periodic waves in anisotropic media of magnetized plasma as well as polymeric fluids under gravity is sufficient to generate a forest of jets.

Iaith wreiddiol	Saesneg
Tudalennau (o-i)	595-600
Nifer y tudalennau	6
Cyfnodolyn	Nature Physics
Cyfrol	18
Rhif cyhoeddi	5
Dyddiad ar-lein cynnar	03 Maw 2022
Dynodwyr Gwrthrych Digidol (DOIs)	https://doi.org/10.1038/s41567-022-01522-1 https://doi.org/10.5281/zenodo.5807020
Statws	Cyhoeddwyd - 01 Mai 2022

Mynediad at Ddogfen

Supplementary informationData, 30.6 MBTrwydded: CC BY
Source dataData, 2.88 KBTrwydded: CC BY

https://github.com/pencil-code/Trwydded: GPLv2
https://iris.lmsal.com/

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Dolen barhaus

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Dolen i’r cyhoeddiad yn Scopus

Solar System Physics at Aberystwyth University
Morgan, H. (Arweinydd y Prosiect), Cook, T. (Cyd‑arweinydd Ymchwil), Gorman, M. (Cyd‑arweinydd Ymchwil), Li, X. (Cyd‑arweinydd Ymchwil), Pinter, B. (Cyd‑arweinydd Ymchwil) & Taroyan, Y. (Cyd‑arweinydd Ymchwil)
Science and Technology Facilities Council
01 Ebr 2019 → 31 Rhag 2022
Prosiect: Ymchwil a ariannwyd yn allanol

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@article{04008cc9465449a4a509816007364d7e,

title = "Polymeric jets throw light on the origin and nature of the forest of solar spicules",

abstract = "Spicules are plasma jets that are observed in the dynamic interface region between the visible solar surface and the hot corona. At any given time, it is estimated that about 3 million spicules are present on the Sun. We find an intriguing parallel between the simulated spicular forest in a solar-like atmosphere and the numerous jets of polymeric fluids when both are subjected to harmonic forcing. In a radiative magnetohydrodynamic numerical simulation with sub-surface convection, solar global surface oscillations are excited similarly to those harmonic vibrations. The jets thus produced match remarkably well with the forests of spicules detected in observations of the Sun. Taken together, the numerical simulations of the Sun and the laboratory fluid dynamics experiments provide insights into the mechanism underlying the ubiquity of jets. The non-linear focusing of quasi-periodic waves in anisotropic media of magnetized plasma as well as polymeric fluids under gravity is sufficient to generate a forest of jets.",

keywords = "driven, dynamics, evolution, Faraday Waves, generation, numerical simulation, small-scale, velocity",

author = "Sahel Dey and Piyali Chatterjee and Murthy, \{O. V.S.N.\} and Kors{\'o}s, \{Marianna B.\} and Jiajia Liu and Nelson, \{Christopher J.\} and Robertus Erd{\'e}lyi",

note = "Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2022",

month = may,

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doi = "10.1038/s41567-022-01522-1",

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T1 - Polymeric jets throw light on the origin and nature of the forest of solar spicules

AU - Dey, Sahel

AU - Chatterjee, Piyali

AU - Murthy, O. V.S.N.

AU - Korsós, Marianna B.

AU - Liu, Jiajia

AU - Nelson, Christopher J.

AU - Erdélyi, Robertus

PY - 2022/5/1

Y1 - 2022/5/1

N2 - Spicules are plasma jets that are observed in the dynamic interface region between the visible solar surface and the hot corona. At any given time, it is estimated that about 3 million spicules are present on the Sun. We find an intriguing parallel between the simulated spicular forest in a solar-like atmosphere and the numerous jets of polymeric fluids when both are subjected to harmonic forcing. In a radiative magnetohydrodynamic numerical simulation with sub-surface convection, solar global surface oscillations are excited similarly to those harmonic vibrations. The jets thus produced match remarkably well with the forests of spicules detected in observations of the Sun. Taken together, the numerical simulations of the Sun and the laboratory fluid dynamics experiments provide insights into the mechanism underlying the ubiquity of jets. The non-linear focusing of quasi-periodic waves in anisotropic media of magnetized plasma as well as polymeric fluids under gravity is sufficient to generate a forest of jets.

AB - Spicules are plasma jets that are observed in the dynamic interface region between the visible solar surface and the hot corona. At any given time, it is estimated that about 3 million spicules are present on the Sun. We find an intriguing parallel between the simulated spicular forest in a solar-like atmosphere and the numerous jets of polymeric fluids when both are subjected to harmonic forcing. In a radiative magnetohydrodynamic numerical simulation with sub-surface convection, solar global surface oscillations are excited similarly to those harmonic vibrations. The jets thus produced match remarkably well with the forests of spicules detected in observations of the Sun. Taken together, the numerical simulations of the Sun and the laboratory fluid dynamics experiments provide insights into the mechanism underlying the ubiquity of jets. The non-linear focusing of quasi-periodic waves in anisotropic media of magnetized plasma as well as polymeric fluids under gravity is sufficient to generate a forest of jets.

KW - driven

KW - dynamics

KW - evolution

KW - Faraday Waves

KW - generation

KW - numerical simulation

KW - small-scale

KW - velocity

UR - https://www.scopus.com/pages/publications/85125593487

U2 - 10.1038/s41567-022-01522-1

DO - 10.1038/s41567-022-01522-1

M3 - Article

SN - 1745-2481

VL - 18

SP - 595

EP - 600

JO - Nature Physics

JF - Nature Physics

IS - 5

ER -

Polymeric jets throw light on the origin and nature of the forest of solar spicules

Crynodeb

Mynediad at Ddogfen

Cysylltiad parhaol

Ffeiliau eraill a chysylltiadau

Ôl bys

Prosiectau

Solar System Physics at Aberystwyth University

Dyfynnu hyn