Eruption of a Buoyantly Emerging Magnetic Flux Rope

Manchester, W.; Gombosi, T. I.; Zeeuw, Darren L. De; Fan, Yuhong

doi:10.1086/421516

Cited by 285 publications

(385 citation statements)

References 24 publications

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“…In order for the magnetic field to remain coherent during this rise, the flux tube must be twisted by a sufficient amount (Moreno-Insertis and Emonet, 1996;Emonet and Moreno-Insertis, 1998). Hence, many researchers (Fan, 2001;Magara and Longcope, 2003;Manchester et al, 2004;Archontis et al, 2004;Murray et al, 2006;MacTaggart and Hood, 2010) have placed a horizontal, cylindrical, twisted flux tube near the top of the convection zone.…”

Section: Initial Sub-photospheric Magnetic Fieldmentioning

confidence: 99%

“…The rapid expansion of the magnetic field creates a region of reduced pressure (as indicated in Figure 4) and this acts as a sink for draining plasma. Apart from this cavitation, the expanding magnetic field produces another dynamically important effect -shearing along the polarity inversion line (PIL) between the two main photospheric polarities (Manchester, 2001;Fan, 2001;Manchester et al, 2004;Hood et al, 2009;MacTaggart and Hood, 2009). This shearing can be understood by examining the Lorentz force in the direction (y in this case) of the PIL, namely − ∂ ∂y…”

Section: Flux Rope Formationmentioning

confidence: 99%

“…While this work was mainly 2D, it laid the foundations for the subsequent 3D simulations. Matsumoto et al (1998) were the first to investigate the emergence of a 3D flux tube from the the solar interior. They investigated how a cylindrical flux tube, unstable to a kink instability (Hood and Priest, 1979), can rise from the interior into the solar atmposhere.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

3D MHD Flux Emergence Experiments: Idealised Models and Coronal Interactions

Hood

Archontis

MacTaggart³

2011

Sol Phys

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This paper reviews some of the many 3D numerical experiments of the emergence of magnetic fields from the solar interior and the subsequent interaction with the pre-existing coronal magnetic field. The models described here are idealized, in the sense that the internal energy equation only involves the adiabatic, Ohmic and viscous shock heating terms. However, provided the main aim is to investigate the dynamical evolution, this is adequate. Many interesting observational phenomena are explained by these models in a self-consistent manner.

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Section: Initial Sub-photospheric Magnetic Fieldmentioning

confidence: 99%

Section: Flux Rope Formationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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3D MHD Flux Emergence Experiments: Idealised Models and Coronal Interactions

Hood

Archontis

MacTaggart³

2011

Sol Phys

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“…Flux rope emergence has many caveats, e.g. in the concave-up parts under the flux rope axis plasma accumulates, leading to a fragmentation of the emerging flux rope (e.g., Magara 2004;Manchester et al 2004) which can only emerge through many smallscale reconnections (Pariat et al 2004). Nevertheless, characteristic magnetic patterns in emerging flux regions originating from the changing azimuthal component of a flux rope while crossing the photosphere, the so-called "magnetic tongues" (López-Fuentes et al 2000;Démoulin & Pariat 2008) indicate that there is an overall organization in the emerging flux tube, which is compatible with a global twist.…”

Section: Origin and Storage Of Free Magnetic Energymentioning

confidence: 99%

Magnetic reconnection and energy release on the Sun and solar-like stars

Driel‐Gesztelyi

2008

Proc. IAU

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Abstract. Magnetic reconnection is thought to play an important role in liberating free energy stored in stressed magnetic fields. The consequences vary from undetectable nanoflares to huge flares, which have signatures over a wide wavelength range, depending on e.g. magnetic topology, free energy content, total flux, and magnetic flux density of the structures involved. Events of small energy release, which are thought to be the most numerous, are one of the key factors in the existence of a hot corona in the Sun and solar-like stars. The majority of large flares are ejective, i.e. involve the expulsion of large quantities of mass and magnetic field from the star. Since magnetic reconnection requires small length-scales, which are well below the spatial resolution limits of even the solar observations, we cannot directly observe magnetic reconnection happening. However, there is a plethora of indirect evidences from X-rays to radio observations of magnetic reconnection. I discuss key observational signatures of flares on the Sun and solar-paradigm stellar flares and describe models emphasizing synergy between observations and theory.

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“…Magnetohydrodynamic (MHD) simulations provide insight into the behavior of twisted flux ropes that emerge from within the convective envelope and currents that are induced by such emergence and by lateral displacements and twisting motions of photospheric field. Manchester et al (2004) and Fang et al (2012), for example, use MHD simulations to show how flux-rope emergence can build up magnetic shear in the corona through shearing flows at the polarity inversion line (PIL) and spot rotation. MHD studies by Török & Kliem (2003), Török et al (2014), and Dalmasse et al (2015) concur in that non-neutralized, i.e., net, electrical currents only occur if the twisting and shearing motions of the flux emergence that they prescribe build up magnetic shear at the PIL.…”

Section: Introductionmentioning

confidence: 99%

The Nonpotentiality of Coronae of Solar Active Regions, the Dynamics of the Surface Magnetic Field, and the Potential for Large Flares

Schrijver

2016

ApJ

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Flares and eruptions from solar active regions (ARs) are associated with atmospheric electrical currents accompanying distortions of the coronal field away from a lowest-energy potential state. In order to better understand the origin of these currents and their role in M-and X-class flares, I review all AR observations made with Solar Dynamics Observatory (SDO)/Helioseismic and Magnetic Imager and SDO/Atmospheric Imaging Assembly from 2010 May through 2014 October within ≈40°from the disk center. I select the roughly 4% of all regions that display a distinctly nonpotential coronal configuration in loops with a length comparable to the scale of the AR, and all that emit GOES X-class flares. The data for 41 regions confirm, with a single exception, that strong-field, high-gradient polarity inversion lines (SHILs) created during emergence of magnetic flux into, and related displacement within, pre-existing ARs are associated with X-class flares. Obvious nonpotentiality in the AR-scale loops occurs in six of ten selected regions with X-class flares, all with relatively long SHILs along their primary polarity inversion line, or with a long internal filament there. Nonpotentiality can exist in ARs well past the flux-emergence phase, often with reduced or absent flaring. I conclude that the dynamics of the flux involved in the compact SHILs is of pre-eminent importance for the large-flare potential of ARs within the next day, but that their associated currents may not reveal themselves in AR-scale nonpotentiality. In contrast, AR-scale nonpotentiality, which can persist for many days, may inform us about the eruption potential other than those from SHILs which is almost never associated with X-class flaring.

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Eruption of a Buoyantly Emerging Magnetic Flux Rope

Cited by 285 publications

References 24 publications

3D MHD Flux Emergence Experiments: Idealised Models and Coronal Interactions

3D MHD Flux Emergence Experiments: Idealised Models and Coronal Interactions

Magnetic reconnection and energy release on the Sun and solar-like stars

The Nonpotentiality of Coronae of Solar Active Regions, the Dynamics of the Surface Magnetic Field, and the Potential for Large Flares

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