Kelvin–Helmholtz instability and Alfvénic vortex shedding in solar eruptions

P. Syntelis; P. Antolin

doi:10.3847/2041-8213/ab44ab

Kelvin–Helmholtz instability and Alfvénic vortex shedding in solar eruptions

P. Syntelis, P. Antolin

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

Abstract

We report on a three-dimensional MHD numerical experiment of a small-scale coronal mass ejection (CME)-like eruption propagating though a nonmagnetized solar atmosphere. We find that the Kelvin–Helmholtz instability (KHI) develops at various but specific locations at the boundary layer between the erupting field and the background atmosphere, depending on the relative angle between the velocity and magnetic field. KHI develops at the front and at two of the four sides of the eruption. KHI is suppressed at the other two sides of the eruption. We also find the development of Alfvénic vortex shedding flows at the wake of the developing CME due to the 3D geometry of the field. Forward modeling reveals that the observational detectability of the KHI in solar eruptions is confined to a narrow ≈10° range when observing off-limb, and therefore its occurrence could be underestimated due to projection effects. The new findings can have significant implications for observations, for heating, and for particle acceleration by turbulence from flow-driven instabilities associated with solar eruptions of all scales.

Original language	English
Article number	L4
Pages (from-to)	1-7
Number of pages	7
Journal	Astrophysical Journal Letters
Volume	884
Issue number	1
Early online date	3 Oct 2019
DOIs	https://doi.org/10.3847/2041-8213/ab44ab
Publication status	Published - 10 Oct 2019

Keywords

Magnetohydrodynamics
Solar activity
Solar active regions
Solar atmosphere
Solar atmospheric motions
Solar corona
Solar coronal mass ejections
Solar magnetic flux emergence
Solar magnetic fields
Magnetohydrodynamical simulations

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10.3847/2041-8213/ab44ab

Syntelis_2019_ApJL_884_L4
Copyright © 2019 American Astronomical Society. This work has been made available online in accordance with publisher policies or with permission. Permission for further reuse of this content should be sought from the publisher or the rights holder. This is the final published version of the work, which was originally published at https://doi.org/10.3847/2041-8213/ab44ab
Final published version, 3.96 MB

http://adsabs.harvard.edu/abs/2019ApJ...884L...4S

1 Finished
1 Active

WholeSun ERC Project: H2020 ERC Synergy Grant Whole Sun Project
Archontis, V. (PI), Archontis, V. (PI), Hood, A. W. (Researcher), Mackay, D. H. (Researcher) & Syntelis, P. (Researcher)
European Research Council
1/05/19 → 30/04/25
Project: Standard
The Cool Alter-Ego of the Hot: The Cool Alter-ego of the Hot Solar Corona
Antolin, P. (PI)
1/06/18 → 31/05/23
Project: Fellowship

Cite this

@article{8272071ab1964b7d8e558e526b0389bf,

title = "Kelvin–Helmholtz instability and Alfv{\'e}nic vortex shedding in solar eruptions",

abstract = "We report on a three-dimensional MHD numerical experiment of a small-scale coronal mass ejection (CME)-like eruption propagating though a nonmagnetized solar atmosphere. We find that the Kelvin–Helmholtz instability (KHI) develops at various but specific locations at the boundary layer between the erupting field and the background atmosphere, depending on the relative angle between the velocity and magnetic field. KHI develops at the front and at two of the four sides of the eruption. KHI is suppressed at the other two sides of the eruption. We also find the development of Alfv{\'e}nic vortex shedding flows at the wake of the developing CME due to the 3D geometry of the field. Forward modeling reveals that the observational detectability of the KHI in solar eruptions is confined to a narrow ≈10° range when observing off-limb, and therefore its occurrence could be underestimated due to projection effects. The new findings can have significant implications for observations, for heating, and for particle acceleration by turbulence from flow-driven instabilities associated with solar eruptions of all scales.",

keywords = "Magnetohydrodynamics, Solar activity, Solar active regions, Solar atmosphere, Solar atmospheric motions, Solar corona, Solar coronal mass ejections, Solar magnetic flux emergence, Solar magnetic fields, Magnetohydrodynamical simulations",

author = "P. Syntelis and P. Antolin",

note = "Funding: UK STFC Ernest Rutherford Fellowship (No. ST/R004285/1) (P.A.). ERC synergy grant “The Whole Sun” (P.S.).",

year = "2019",

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doi = "10.3847/2041-8213/ab44ab",

language = "English",

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T1 - Kelvin–Helmholtz instability and Alfvénic vortex shedding in solar eruptions

AU - Syntelis, P.

AU - Antolin, P.

N1 - Funding: UK STFC Ernest Rutherford Fellowship (No. ST/R004285/1) (P.A.). ERC synergy grant “The Whole Sun” (P.S.).

PY - 2019/10/10

Y1 - 2019/10/10

N2 - We report on a three-dimensional MHD numerical experiment of a small-scale coronal mass ejection (CME)-like eruption propagating though a nonmagnetized solar atmosphere. We find that the Kelvin–Helmholtz instability (KHI) develops at various but specific locations at the boundary layer between the erupting field and the background atmosphere, depending on the relative angle between the velocity and magnetic field. KHI develops at the front and at two of the four sides of the eruption. KHI is suppressed at the other two sides of the eruption. We also find the development of Alfvénic vortex shedding flows at the wake of the developing CME due to the 3D geometry of the field. Forward modeling reveals that the observational detectability of the KHI in solar eruptions is confined to a narrow ≈10° range when observing off-limb, and therefore its occurrence could be underestimated due to projection effects. The new findings can have significant implications for observations, for heating, and for particle acceleration by turbulence from flow-driven instabilities associated with solar eruptions of all scales.

AB - We report on a three-dimensional MHD numerical experiment of a small-scale coronal mass ejection (CME)-like eruption propagating though a nonmagnetized solar atmosphere. We find that the Kelvin–Helmholtz instability (KHI) develops at various but specific locations at the boundary layer between the erupting field and the background atmosphere, depending on the relative angle between the velocity and magnetic field. KHI develops at the front and at two of the four sides of the eruption. KHI is suppressed at the other two sides of the eruption. We also find the development of Alfvénic vortex shedding flows at the wake of the developing CME due to the 3D geometry of the field. Forward modeling reveals that the observational detectability of the KHI in solar eruptions is confined to a narrow ≈10° range when observing off-limb, and therefore its occurrence could be underestimated due to projection effects. The new findings can have significant implications for observations, for heating, and for particle acceleration by turbulence from flow-driven instabilities associated with solar eruptions of all scales.

KW - Magnetohydrodynamics

KW - Solar activity

KW - Solar active regions

KW - Solar atmosphere

KW - Solar atmospheric motions

KW - Solar corona

KW - Solar coronal mass ejections

KW - Solar magnetic flux emergence

KW - Solar magnetic fields

KW - Magnetohydrodynamical simulations

U2 - 10.3847/2041-8213/ab44ab

DO - 10.3847/2041-8213/ab44ab

M3 - Article

SN - 2041-8205

VL - 884

SP - 1

EP - 7

JO - Astrophysical Journal Letters

JF - Astrophysical Journal Letters

IS - 1

M1 - L4

ER -

Kelvin–Helmholtz instability and Alfvénic vortex shedding in solar eruptions

Abstract

Keywords

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Projects

WholeSun ERC Project: H2020 ERC Synergy Grant Whole Sun Project

The Cool Alter-Ego of the Hot: The Cool Alter-ego of the Hot Solar Corona

Cite this