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

^*Corresponding author for this work

Department of Physics

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

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.

Original language	English
Pages (from-to)	595-600
Number of pages	6
Journal	Nature Physics
Volume	18
Issue number	5
Early online date	03 Mar 2022
DOIs	https://doi.org/10.1038/s41567-022-01522-1 https://doi.org/10.5281/zenodo.5807020
Publication status	Published - 01 May 2022

Keywords

driven
dynamics
evolution
Faraday Waves
generation
numerical simulation
small-scale
velocity

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Supplementary informationData, 30.6 MBLicence: CC BY
Source dataData, 2.88 KBLicence: CC BY

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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 = "Funding Information: Computing time provided by Nova HPC at IIA as well as Param Yukti facility at JNCASR under National Supercomputing Mission, Govt. of India is gratefully acknowledged. This work has also utilized SahasraT facility at SERC, IISc for computing and CENSe, IISc for rheometry. S.D. and P.C. thank IIA for financial support towards the usage of SahasraT. S.D. also acknowledges the SOLARNET project that has received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation programme under grant agreement no. 824135. M.O.V.S.N. acknowledges a grant RC00226 to study Faraday oscillations in fluids from the Azim Premji University. M.B.K. thanks the Science and Technology Facilities Council (STFC) for the ST/S000518/1 grant. J.L. acknowledges the support from the Leverhulme Trust via grant RPG-2019-371. C.J.N. thanks STFC for the support received to conduct this research through grant nos. ST/P000304/1 and ST/T00021X/1. R.E. is grateful to STFC (grant no. ST/M000826/1), the Royal Society and the President{\textquoteright}s International Fellowship Initiative of the Chinese Academy of Sciences (grant no. 2019VMA052) for enabling this research. R.E. also acknowledges the support received from the Higher Education Programme of Excellence for Particle and Astrophysics, E{\"o}tv{\"o}s L. University (Budapest, Hungary). We thank C. Kalelkar for several discussions on polymeric fluids. IRIS is a NASA small explorer mission developed and operated by LMSAL with major contributions to downlink communications funded by ESA and the Norwegian Space Centre. The accelerated solar global p mode observations used to construct Supplementary Video 5 were obtained by the SoHO/MDI instrument. We used the visualisation software Paraview for volume rendering for Supplementary Video 3. Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

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

language = "English",

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AU - Chatterjee, Piyali

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

AU - Korsós, Marianna B.

AU - Liu, Jiajia

AU - Nelson, Christopher J.

AU - Erdélyi, Robertus

N1 - Funding Information: Computing time provided by Nova HPC at IIA as well as Param Yukti facility at JNCASR under National Supercomputing Mission, Govt. of India is gratefully acknowledged. This work has also utilized SahasraT facility at SERC, IISc for computing and CENSe, IISc for rheometry. S.D. and P.C. thank IIA for financial support towards the usage of SahasraT. S.D. also acknowledges the SOLARNET project that has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement no. 824135. M.O.V.S.N. acknowledges a grant RC00226 to study Faraday oscillations in fluids from the Azim Premji University. M.B.K. thanks the Science and Technology Facilities Council (STFC) for the ST/S000518/1 grant. J.L. acknowledges the support from the Leverhulme Trust via grant RPG-2019-371. C.J.N. thanks STFC for the support received to conduct this research through grant nos. ST/P000304/1 and ST/T00021X/1. R.E. is grateful to STFC (grant no. ST/M000826/1), the Royal Society and the President’s International Fellowship Initiative of the Chinese Academy of Sciences (grant no. 2019VMA052) for enabling this research. R.E. also acknowledges the support received from the Higher Education Programme of Excellence for Particle and Astrophysics, Eötvös L. University (Budapest, Hungary). We thank C. Kalelkar for several discussions on polymeric fluids. IRIS is a NASA small explorer mission developed and operated by LMSAL with major contributions to downlink communications funded by ESA and the Norwegian Space Centre. The accelerated solar global p mode observations used to construct Supplementary Video 5 were obtained by the SoHO/MDI instrument. We used the visualisation software Paraview for volume rendering for Supplementary Video 3. Publisher Copyright: © 2022, The Author(s), under exclusive licence to Springer Nature Limited.

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

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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

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

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