Prominence formation by levitation-condensation at extreme resolutions

Jenkins, Jack; Keppens, Rony

doi:10.1051/0004-6361/202039630

Cited by 30 publications

(21 citation statements)

References 92 publications

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“…In fact, as concluded by Low (1996), the total mass of a flux rope should play an important role in stabilizing the rope, which is further confirmed by some recent studies (Hillier & van Ballegooijen 2013;Jenkins et al 2019;Tsap et al 2019;Fan 2020). Moreover, the total mass of a flux rope is usually not conserved but highly dynamic Gibson 2018): it either accumulates via, e.g., coronal condensation (Liu et al 2012;Xia & Keppens 2016;Jenkins & Keppens 2021), or decreases as a result of, e.g., mass unloading (Low 1996) and mass drainage processes (Bi et al 2014;Jenkins et al 2019). Therefore, to understand the influence of the varying mass on the catastrophic behaviors of coronal flux ropes is not only important to improve flux rope catastrophe theory, but also shed light on the physical scenario of different kinds of flux rope activities.…”

Section: Introductionmentioning

confidence: 62%

Confined and eruptive catastrophes of solar magnetic flux ropes caused by mass loading and unloading

Zhang,

Liu,

Wang

et al. 2021

Preprint

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It is widely accepted that coronal magnetic flux ropes are the core structures of large-scale solar eruptive activities, which inflict dramatic impacts on the solarterrestrial system. Previous studies have demonstrated that varying magnetic properties of a coronal flux rope system could result in a catastrophe of the rope, which may trigger solar eruptive activities. Since the total mass of a flux rope also plays an important role in stabilizing the rope, we use 2.5-dimensional magnetohydrodynamic (MHD) numerical simulations in this letter to investigate how a flux rope evolves as its total mass varies. It is found that an unloading process that decreases the total mass of the rope could result in an upward (eruptive) catastrophe in the flux rope system, during which the rope jumps upward and the magnetic energy is released. This indicates that mass unloading processes could initiate the eruption of the flux rope. Moreover, when the system is not too diffusive, there is also a downward (confined) catastrophe that could be caused by mass loading processes, via which the total mass accumulates. The magnetic energy, however, is increased during the downward catastrophe, indicating that mass loading processes could cause confined activities that may contribute to the storage of energy before the onset of coronal eruptions.

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Section: Introductionmentioning

confidence: 62%

Confined and eruptive catastrophes of solar magnetic flux ropes caused by mass loading and unloading

Zhang,

Liu,

Wang

et al. 2021

Preprint

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“…The formation mechanisms of prominences are still puzzling. There are various models accounting for prominence formation as reviewed by Mackay et al (2010), and the models include levitation of chromospheric plasma (Zhao et al 2017(Zhao et al , 2019Zhao & Keppens 2020), evaporation-condensation Xia et al 2011Xia et al , 2014Xia & Keppens 2016), injection (An et al 1988;Wang 1999;Guo et al 2019), or more mixed models such as levitationcondensation of purely coronal plasma (Jenkins & Keppens 2021), as well as the three-dimensional prominence formation model by reconnection-condensation as pro-posed by Kaneko & Yokoyama (2017) and the prominence eruption model by Fan (2018).…”

Section: Introductionmentioning

confidence: 99%

Plasmoid-fed prominence formation (PF$^2$) during flux rope eruption

Zhao,

Keppens

2022

Preprint

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We report a new, plasmoid-fed scenario for the formation of an eruptive prominence (PF 2 ), involving reconnection and condensation. We use grid-adaptive resistive two-and-a-half-dimensional magnetohydrodynamic (MHD) simulations in a chromosphere-to-corona setup to resolve this plasmoid-fed scenario. We study a pre-existing flux rope (FR) in the low corona that suddenly erupts due to catastrophe, which also drives a fast shock above the erupting FR. A current sheet (CS) forms underneath the erupting FR, with chromospheric matter squeezed into it. The plasmoid instability occurs and multiple magnetic islands appear in the CS once the Lundquist number reaches ∼ 3.5 × 10 4 . The remnant chromospheric matter in the CS is then transferred to the FR by these newly formed magnetic islands. The dense and cool mass transported by the islands accumulates in the bottom of the FR, thereby forming a prominence during the eruption phase. More coronal plasma continuously condenses into the prominence due to the thermal instability as the FR rises. Due to the fine structure brought in by the PF 2 process, the model naturally forms filament threads, aligned above the polarity inversion line. Synthetic views at our resolution of 15km show many details that may be verified in future high-resolution observations.

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“…Solar prominences are cool and dense plasma suspended in the hot corona (Mackay et al 2010;Parenti 2014). They usually form through direct injection (Chae et al 2000), evaporationcondensation (Karpen et al 2005, Huang et al 2021, or levitation-condensation (Jenkins & Keppens 2021) processes along the magnetic polarity inversion lines (van Ballegooijen & Martens 1989). The lifetimes of prominences range from a few weeks to a few months.…”

Section: Introductionmentioning

confidence: 99%

A revised cone model and its application to non-radial prominence eruptions

Zhang

2021

A&A

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Context. The traditional cone models achieve great success in studying the geometrical and kinematic properties of halo coronal mass ejections (CMEs). Aims. In this Letter, a revised cone model is proposed to investigate the properties of CMEs as a result of non-radial prominence eruptions. Methods. The cone apex is located at the source region of an eruption instead of the Sun center. The cone axis deviates from the local vertical by an inclination angle of θ1 and an angle of ϕ1. The length and angular width of the cone are r and ω, respectively. Results. The model was successfully applied to two CMEs originating from the western limb on 2011 August 11 and 2012 December 7. By comparing the projections of the cones with the CME fronts simultaneously observed by the Atmospheric Imaging Assembly on board the Solar Dynamics Observatory and the Extreme-Ultraviolet Imager on board the ahead Solar TErrestrial RElations Observatory, the properties of the CMEs were derived, including the distance, angular width, inclination angle, deviation from the plane of the sky, and true speed in space. Conclusions. This revised cone model provides a new and complementary approach in exploring the whole evolutions of CMEs.

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Prominence formation by levitation-condensation at extreme resolutions

Cited by 30 publications

References 92 publications

Confined and eruptive catastrophes of solar magnetic flux ropes caused by mass loading and unloading

Confined and eruptive catastrophes of solar magnetic flux ropes caused by mass loading and unloading

Plasmoid-fed prominence formation (PF$^2$) during flux rope eruption

A revised cone model and its application to non-radial prominence eruptions

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