Nonlinear Dynamics of the Parker Scenario for Coronal Heating

Rappazzo, A. F.; Velli, Marco; Einaudi, G.; Dahlburg, R. B.

doi:10.1086/528786

Cited by 211 publications

(372 citation statements)

References 48 publications

(67 reference statements)

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“…1 of [90]). In that original work, the magnetic field is (roughly) constant in space, which is similar to three-dimensional experiments without gravity [15]. Therefore, also the currents and thus the Ohmic heating will be (roughly) constant in space.…”

Section: (E) Nanoflares Nanoflare Storms and Braiding Of Fieldlinesmentioning

confidence: 60%

“…In particular, these models will also describe the variability of the heating in the direction perpendicular to the fieldlines. Solving a simplified problem, it has been shown that current sheets are roughly aligned with the magnetic field and result in a heat input intermittent in space and time [13,15]. These current sheets are also seen in three-dimensional models in a more realistic atmospheric set-up (albeit at a reduced resolution) as narrow fingers of enhanced heat input; see figs.…”

Section: (B) Heat Input With Height and Along Individual Fieldlinesmentioning

confidence: 95%

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What can large-scale magnetohydrodynamic numerical experiments tell us about coronal heating?

Peter

2015

Phil. Trans. R. Soc. A.

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The upper atmosphere of the Sun is governed by the complex structure of the magnetic field. This controls the heating of the coronal plasma to over a million kelvin. Numerical experiments in the form of threedimensional magnetohydrodynamic simulations are used to investigate the intimate interaction between magnetic field and plasma. These models allow one to synthesize the coronal emission just as it would be observed by real solar instrumentation. Largescale models encompassing a whole active region form evolving coronal loops with properties similar to those seen in extreme ultraviolet light from the Sun, and reproduce a number of average observed quantities. This suggests that the spatial and temporal distributions of the heating as well as the energy distribution of individual heat deposition events in the model are a good representation of the real Sun. This provides evidence that the braiding of fieldlines through magneto-convective motions in the photosphere is a good concept to heat the upper atmosphere of the Sun.

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Section: (E) Nanoflares Nanoflare Storms and Braiding Of Fieldlinesmentioning

confidence: 60%

Section: (B) Heat Input With Height and Along Individual Fieldlinesmentioning

confidence: 95%

What can large-scale magnetohydrodynamic numerical experiments tell us about coronal heating?

Peter

2015

Phil. Trans. R. Soc. A.

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“…Such braiding is a measure of how often different field lines cross each other in space Berger and Asgari-Targhi 2009 and is supported by MHD models (Gudiksen and Nordlund 2005;Rappazzo et al 2008;van Ballegooijen et al 2011). These braided small-scale field structures efficiently heat the coronal environment by the dissipation of electric currents, where oppositely directed magnetic fields are found in close vicinity to each other (Parker 1983, see also Cirtain et al 2013;Thalmann et al 2014).…”

Section: Energy Buildup and Storagementioning

confidence: 94%

The magnetic field in the solar atmosphere

Wiegelmann

Thalmann

Solanki

2014

Astron Astrophys Rev

176

125

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This publication provides an overview of magnetic fields in the solar atmosphere with the focus lying on the corona. The solar magnetic field couples the solar interior with the visible surface of the Sun and with its atmosphere. It is also responsible for all solar activity in its numerous manifestations. Thus, dynamic phenomena such as coronal mass ejections and flares are magnetically driven. In addition, the field also plays a crucial role in heating the solar chromosphere and corona as well as in accelerating the solar wind. Our main emphasis is the magnetic field in the upper solar atmosphere so that photospheric and chromospheric magnetic structures are mainly discussed where relevant for higher solar layers. Also, the discussion of the solar atmosphere and activity is limited to those topics of direct relevance to the magnetic field. After giving a brief overview about the solar magnetic field in general and its global structure, we discuss in more detail the magnetic field in active regions, the quiet Sun and coronal holes.

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“…The first family of these models involve transient and alternative currents (AC), either created by MHD turbulence (e.g. Buchlin et al 2003;Gudiksen & Nordlund 2005;Rappazzo et al 2008) or by the resistive damping of nonlinear magnetoacoustic waves (e.g. Heyvaerts & Priest 1983;Einaudi & Mok 1987;Parker 1991;Ofman & Davila 1995).…”

Section: Introductionmentioning

confidence: 99%

How skeletons turn into quasi-separatrix layers in source models

Restante

Aulanier²,

Parnell

2009

A&A

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Context. In situations where there are no magnetic null points located above a reference photospheric plane, and when the photospheric magnetic field is modeled by discrete flux concentrations, the magnetic connectivity is defined by the magnetic skeleton of the configuration. For a continuous distribution of non-zero photospheric flux, the connectivity is defined by quasi-separatrix layers (QSLs). Both the magnetic skeleton and QSLs can account for current sheet formation and dissipation. Observationally, though, only some portions of the skeleton are found to be related to flare ribbons, which are generally associated with QSL footpoints. Aims. In potential magnetic source models, a transition from the skeleton to QSLs has been shown to occur when the sources are displaced below the photospheric plane. The objective of this paper is to understand the topological and geometrical nature of this transition, and to derive rules to predict which parts of a given skeleton will give rise to QSLs. Methods. We consider magnetic configurations, derived from potential magnetic sources, which possess no coronal null points. We have calculated their skeletons, composed of null points, spine field lines and separatrix (fan) surfaces. Choosing a reference photospheric plane above the sources, we have calculated their QSL footprints. Results. As already known, the latter mostly match with subphotospheric spine field lines since, above these lines, field lines tend to diverge as a result of approaching a null and lying either side of the separatrix surface extending out of from this null. However, many non-spine related QSL footprints are also found, which we call branches. They correspond to the intersection with the photosphere of portions of fan field lines which "branch" away from the sources and result in QSLs due to the inclination of the coronal field lines. Conclusions. Our findings allow a better geometrical understanding of the relations between QSLs and skeletons. We show that in the absence of coronal null points, spines, as well as specific portions of fans as calculated in standard potential source models, are good predictors for the location of QSL footprints and of flare ribbons.

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Nonlinear Dynamics of the Parker Scenario for Coronal Heating

Cited by 211 publications

References 48 publications

What can large-scale magnetohydrodynamic numerical experiments tell us about coronal heating?

What can large-scale magnetohydrodynamic numerical experiments tell us about coronal heating?

The magnetic field in the solar atmosphere

How skeletons turn into quasi-separatrix layers in source models

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