A Comparative Study of the Eruptive and Non-eruptive Flares Produced by the Largest Active Region of Solar Cycle 24

Sarkar, Ranadeep; Srivastava, Nandita

doi:10.1007/s11207-017-1235-8

Cited by 26 publications

(21 citation statements)

References 65 publications

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“…The notable, intriguing counterexample of NOAA AR 12192 that hosted a large number of confined flares (e.g. [197]), possibly due to properties of the overlying magnetic field, eventually gave way to a single CME [198] before rotating to the far side. Substantial discussion has been already devoted to this exceptional target that warrants further investigation.…”

Section: Discussionmentioning

confidence: 99%

The source and engine of coronal mass ejections

Georgoulis

Nindos

Zhang

2019

Phil. Trans. R. Soc. A.

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Coronal mass ejections (CMEs) are large-scale expulsions of coronal plasma and magnetic field propagating through the heliosphere. Because CMEs are observed by white-light coronagraphs which, by design, occult the solar disc, supporting disc observations (e.g. in EUV, soft X-rays, Halpha and radio) must be employed for the study of their source regions and early development phases. We review the key properties of CME sources and highlight a certain causal sequence of effects that may occur whenever a strong (flux-massive and sheared) magnetic polarity inversion line develops in the coronal base of eruptive active regions (ARs). Storing non-potential magnetic energy and helicity in a much more efficient way than ARs lacking strong polarity inversion lines, eruptive regions engage in an irreversible course, making eruptions inevitable and triggered when certain thresholds of free energy and helicity are crossed. This evolution favours the formation of pre-eruption magnetic flux ropes. We describe the steps of this plausible path to sketch a picture of the pre-eruptive phase of CMEs that may apply to most events, particularly the ones populating the high end of the energy/helicity distribution, that also tend to have the strongest space-weather implications. This article is part of the theme issue ‘Solar eruptions and their space weather impact’.

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Section: Discussionmentioning

confidence: 99%

The source and engine of coronal mass ejections

Georgoulis

Nindos

Zhang

2019

Phil. Trans. R. Soc. A.

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“…As the flare related major changes in horizontal magnetic field and Lorentz forces are expected to occur close to the polarity inversion line (PIL) (Wang 2006;Petrie & Sudol 2010;Petrie 2012;Sarkar & Srivastava 2018), we have selected subdomains (shown by the region enclosed by the green rectangular boxes in Figure 1) near the PIL on the flare productive part of each AR to carry out our analysis. As the recurrent flares studied in this paper occurred from the same part of the PIL, we are able to capture the evolution of the magnetic field over several days including the time of each flares within that same selected domain on the AR.…”

Section: Discussionmentioning

confidence: 99%

Lorentz Force Evolution Reveals the Energy Build-up Processes during Recurrent Eruptive Solar Flares

Sarkar

Srivastava

Veronig

2019

ApJL

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The energy release and build-up processes in the solar corona have significant implications in particular for the case of large recurrent flares, which pose challenging questions about the conditions that lead to the episodic energy release processes. It is not yet clear whether these events occur due to the continuous supply of free magnetic energy to the solar corona or because not all of the available free magnetic energy is released during a single major flaring event. In order to address this question, we report on the evolution of photospheric magnetic field and the associated net Lorentz force changes in ARs 11261 and 11283, each of which gave rise to recurrent eruptive M-and X-class flares. Our study reveals that after the abrupt downward changes during each flare, the net Lorentz force increases by (2-5) × 10 22 dyne in between the successive flares. This distinct rebuild-up of net Lorentz forces is the first observational evidence found in the evolution of any non-potential parameter of solar active regions (ARs), which suggests that new energy was supplied to the ARs in order to produce the recurrent large flares. The rebuild-up of magnetic free energy of the ARs is further confirmed by the observations of continuous shearing motion of moving magnetic features of opposite polarities near the polarity inversion line. The evolutionary pattern of the net Lorentz force changes reported in this study has significant implications, in particular, for the forecasting of recurrent large eruptive flares from the same AR and hence the chances of interaction between the associated CMEs.

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“…The decay index in the flare-rich but CME-poor active region NOAA 12192 (2014 October) was lower than in CME-productive regions; n did not reach a value of 1.5 until a large height of more than 120 Mm, so the torus instability was unlikely (Sun et al 2015). The decisive role of the decay index heightdependence for the active-region CME-productivity was confirmed in many other flares (Vasantharaju et al 2018;Sarkar & Srivastava 2018).…”

Section: Introductionmentioning

confidence: 93%

Failed prominence eruptions near 24 cycle maximum

Filippov

2020

Monthly Notices of the Royal Astronomical Society

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We analyze 16 failed filament eruptions observed near 24 solar cycle maximum from May 2013 to July 2014. No significant rotation of filament spines is observed during the ascent in all studied failed eruptions, which does not support kink-instability mechanism of triggering the eruptions. We calculate potential magnetic field distributions in the corona above the initial locations of the filaments to study their height dependence. In seven events, the vertical profiles of the decay index n are monotonic. The other nine events occur in the regions with the switchback or saddle-like n-profiles. The direction of the horizontal field near the saddle bottom is turned through more than 100 • relative its direction at the initial filament position, which reveals the quadrupolar magnetic configuration with null points in these regions. The eruptive filaments stop above the null points where the total Lorenz force is directed upward. The most reasonable force that can terminate filament ascending and balance the Lorenz force seems the gravity.

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A Comparative Study of the Eruptive and Non-eruptive Flares Produced by the Largest Active Region of Solar Cycle 24

Cited by 26 publications

References 65 publications

The source and engine of coronal mass ejections

The source and engine of coronal mass ejections

Lorentz Force Evolution Reveals the Energy Build-up Processes during Recurrent Eruptive Solar Flares

Failed prominence eruptions near 24 cycle maximum

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