Coronal rain in randomly heated arcades

Li, Xiaohong; Keppens, Rony; Zhou, Yuhao

doi:10.48550/arxiv.2112.02702

Cited by 1 publication

(2 citation statements)

References 81 publications

(168 reference statements)

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“…These mechanisms usually require the magnetic field topology local to the condensations to be concave upwards with respect to gravity; levitation against gravity is facilitated by means of the magnetic Lorentz force (pressure and tension), as first shown by the self-similar model of Kippenhahn and Schlüter (1957). Generally speaking, two main formation processes are discerned: (i) evaporationcondensation, where localised footpoint heating of a magnetic arcade produces upflows which collect in any preexisting dipped fields (Xia et al 2012(Xia et al , 2014Xia and Keppens 2016) -a theory shared with the phenomenon of coro-nal rain (Li et al 2021); and (ii) levitation-condensation Yokoyama 2015, 2018;Jenkins and Keppens 2021) or its variant reconnection-condensation (Kaneko and Yokoyama 2017), where a flux rope is dynamically formed through shearing and converging motions at lower altitudes -a sheared magnetic arcade, whose footpoints are subject to those motions, eventually changes internal connectivity via magnetic reconnection and builds a twisted, helical field (van Ballegooijen and Martens 1989). In doing so, the reconnection may redistribute or scoop up material from the chromosphere or lower corona, which remains suspended by the flux rope (levitation).…”

Section: Introductionmentioning

confidence: 99%

“…dipped fields (Xia et al 2012(Xia et al , 2014Xia and Keppens 2016) -a theory shared with the phenomenon of coronal rain (Li et al 2021); and (ii) the levitation-condensation model Yokoyama 2015, 2018;Jenkins and Keppens 2021) or its variant reconnection-condensation (Kaneko and Yokoyama 2017), where a flux rope is dynamically formed through shearing and converging motions at lower altitudes -a sheared magnetic arcade, whose footpoints are subject to those motions, eventually changes internal connectivity via magnetic reconnection and builds a twisted, helical field (van Ballegooijen and Martens 1989). In doing so, the reconnection may redistribute or scoop up material from the chromosphere or lower corona, which remains suspended by the flux rope (levitation).…”

Section: Introductionmentioning

confidence: 99%

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The influence of flux rope heating models on solar prominence formation

Jenkins

Keppens

2022

A&A

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Context. Prominences are cool, dense clouds suspended within the solar corona. Their in situ formation through the levitation-condensation mechanism is a textbook example of the thermal instability, where a slight energy imbalance leads to a runaway process resulting in condensed filamentary structures embedded within the concave-up portions of a flux rope. The detailed interplay between local radiative losses and the global heating of the solar corona is investigated here for prominence-forming flux rope structures. Aims. We begin by exploring the influence of two classes of commonly adopted heating models on the formation behaviour of solar prominences. These models consider either an exponential variation dependent on height alone, or local density and magnetic field conditions. We highlight and address some of the limitations inherent to these early approximations by proposing a new, dynamic 2D flux rope heating model that qualitatively accounts for the 3D topology of the twisted flux rope field. Methods. We performed 2.5D grid-adaptive numerical simulations of prominence formation via the levitationcondensation mechanism. A linear force-free arcade is subjected to shearing and converging motions, leading to the formation of a flux rope containing material that may succumb to thermal instability. The eventual formation and subsequent evolution of prominence condensations was then quantified as a function of the specific background heating prescription adopted. For the simulations that consider the topology of the flux rope, reduced heating was considered within a dynamically evolving ellipse that traces the flux rope cross-section. This ellipse is centred on the flux rope axis and tracked during runtime using an approach based on the instantaneous magnetic field curvature. Results. We find that the nature of the heating model is clearly imprinted on the evolution and morphology of any resulting prominences: one large, low-altitude condensation is obtained for the heating model based on local parameters, while the exponential model leads to the additional formation of smaller blobs throughout the flux rope which then relocate as they tend towards achieving hydrostatic equilibrium. Finally, a study of the condensation process in phase space reveals a non-isobaric evolution with an eventual recovery of uniform pressure balance along flux surfaces.

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