Preflare Processes, Flux Rope Activation, Large-scale Eruption, and Associated X-class Flare from the Active Region NOAA 11875

Mitra, Prabir K.; Joshi, Bhuwan

doi:10.3847/1538-4357/ab3a96

Cited by 26 publications

(16 citation statements)

References 122 publications

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“…Therefore, the existence of prominence can be considered as an indicator of the magnetic FR in solar corona (Schmieder et al 2013;Filippov et al 2015). The relationship between the FR rise and associated radiative signatures has been a topic of considerable interest (e.g., Alexander et al 2006;Liu et al 2009b;Joshi et al 2013Joshi et al , 2016Mitra & Joshi 2019). In particular, comparisons of the location, timing, and strength of high-energy emissions (e.g., temporal and spatial evolution of HXR sources) with respect to the dynamical evolution of the prominence provide critical clues to help understand the characteristics of the underlying energy release phenomena, such as the expected site of magnetic reconnection, particle acceleration, and heating.…”

Section: Introductionmentioning

confidence: 99%

Observations of a prominence eruption and loop contraction

Devi

Démoulin

Chandra

et al. 2021

A&A

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Context. Prominence eruptions provide key observations to understand the launch of coronal mass ejections as their cold plasma traces a part of the unstable magnetic configuration. Aims. We select a well observed case to derive observational constraints for eruption models. Methods. We analyze the prominence eruption and loop expansion and contraction observed on 02 March 2015 associated with a GOES M3.7 class flare (SOL2015-03-02T15:27) using the data from Atmospheric Imaging Assembly (AIA) and the Reuven Ramaty High Energy Solar Spectroscopic Imager (RHESSI). We study the prominence eruption and the evolution of loops using the time-distance techniques. Results. The source region is a decaying bipolar active region where magnetic flux cancellation is present for several days before the eruption. AIA observations locate the erupting prominence within a flux rope viewed along its local axis direction. We identify and quantify the motion of loops in contraction and expansion located on the side of the erupting flux rope. Finally, RHESSI hard X-ray observations identify the loop top and two foot-point sources. Conclusions. Both AIA and RHESSI observations support the standard model of eruptive flares. The contraction occurs 19 min after the start of the prominence eruption indicating that this contraction is not associated with the eruption driver. Rather, this prominence eruption is compatible with an unstable flux rope where the contraction and expansion of the lateral loop is the consequence of a side vortex developing after the flux rope is launched.

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Section: Introductionmentioning

confidence: 99%

Observations of a prominence eruption and loop contraction

Devi

Démoulin

Chandra

et al. 2021

A&A

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“…Now, the appearance of 'classical' flare signatures, viz., distinct coronal and footpoint HXR sources along with inner flare ribbons formed at both sides of PIL, provide evidence of large-scale magnetic reconnection, which are attributed to the reconnection-opening of overlying field lines (i.e., progression of reconnection in higher coronal fields of the envelope region) stretched by the erupting MFR. The sudden transition in the kinematic evolution of MFR from the phase of slow to fast rise precisely divides the pre-flare and impulsive phase of the flare, which we attribute to the feedback relationship between the early CME dynamics and the strength of the large-scale magnetic reconnection (Temmer et al 2008;Vršnak 2016;Song et al 2018;Mitra & Joshi 2019).…”

Section: Conclusion and Discussionmentioning

confidence: 78%

“…The statistical studies carried out with SXR images from Yohkoh, revealed three categories of pre-flare activities in terms of source locations: co-spatial, adjacent, and remote (Fárník & Savy 1998;Kim et al 2008). The co-spatial and adjacent cases occurring within few minutes before the main flare are supposed to have direct relevance for the triggering processes related to the main flare (Liu et al 2009;Joshi et al 2011;Mitra & Joshi 2019). Notably, EUV and X-ray images clearly show that the pre-flare brightenings are spatially distributed along the hot channel (i.e., MFR) and within the core field region.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

“…It has been observed that many flares are associated with pre-flare and precursor activities, which include small-scale brightness enhancements in the flaring region of about a few to tens of minutes prior to its impulsive phase (Veronig et al 2002;Kundu et al 2004;Joshi et al 2011Joshi et al , 2013Mitra et al 2020). While the precursor phase often shows a direct link to the later eruptive phenomenon, the pre-flare activity is viewed as a single or multiple series of small-scale reconnection events within the active region and may indirectly support the eruption by changing the magnetic and plasma conditions favorably (Fárník et al 1996;Fárník & Savy 1998;Chifor et al 2006;Joshi et al 2011Joshi et al , 2013Mitra & Joshi 2019). Arguably the observations of pre-flare or precursor activity have potential to provide insight on the build-up phase of MFR and the triggering mechanism of the subsequent solar eruption.…”

Section: Introductionmentioning

confidence: 99%

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HXR emission from an activated flux rope and subsequent evolution of an eruptive long duration solar flare

Sahu,

Joshi,

Mitra

et al. 2020

Preprint

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In this paper, we present a comprehensive study of the evolutionary phases of a major M6.6 long duration event (LDE) with special emphasize on its pre-flare phase. The event occurred in NOAA 12371 on 2015 June 22. A remarkable aspect of the event was an active pre-flare phase lasting for about an hour during which a hot EUV coronal channel was in build-up stage and displayed co-spatial hard X-ray (HXR) emission up to energies of 25 keV. As such, this is the first evidence of HXR coronal channel. The coronal magnetic field configuration based on NLFFF modeling clearly exhibited a magnetic flux rope (MFR) oriented along the polarity inversion line (PIL) and co-spatial with the coronal channel. We observed significant changes in the AR's photospheric magnetic field during an extended period of ≈42 hours in the form of rotation of sunspots, moving magnetic features, and flux cancellation along the PIL. Prior to the flare onset, the MFR underwent a slow rise phase (≈14 km s −1 ) for ≈12 min which we attribute to the faster build-up and activation of the MFR by tethercutting reconnection occurring at multiple locations along the MFR itself. The sudden transition in the kinematic evolution of the MFR from the phase of slow to fast rise (≈109 km s −1 with acceleration ≈110 m s −2 ) precisely divides the pre-flare and impulsive phase of the flare, which points toward the feedback process between the early dynamics of the eruption and the strength of the flare magnetic reconnection.

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“…Flux ropes are defined by a set of magnetic field lines that are wrapped around each other in a braided fashion or wrapped around a central axis (braided and twisted flux ropes, respectively, see; Prior & Yeates 2016). Observationally, a flux rope can be identified in different forms: filament (Zirin 1988;Martin 1998), prominence (Tandberg-Hanssen 1995;Parenti 2014), coronal cavity (Forland et al 2013;Gibson 2015), hot channel (Zhang et al 2012;Cheng et al 2013;Mitra & Joshi 2019;Sahu et al 2020), coronal sigmoid (Rust & Kumar 1996;Manoharan et al 1996;Joshi et al 2017a;Mitra et al 2018) etc. The processes involved in the triggering of a flux rope from its stable condition and its successive evolution within the source region are rather complex and debatable (see e.g., Chatterjee & Fan 2013; Kumar et al 2016;Prasad et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Successive occurrences of quasi-circular ribbon flares in a fan-spine-like configuration involving hyperbolic flux tube

Mitra,

Joshi

2021

Preprint

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We present a comprehensive analysis of the formation and evolution of a fan-spine-like configuration that developed over a complex photospheric configuration where dispersed negative polarity regions were surrounded by positive polarity regions. This unique photospheric configuration, analogous to the geological "atoll" shape, hosted four homologous flares within its boundary. Computation of the degree of squashing factor (Q) maps clearly revealed an elongated region of high Q-values between the inner and outer spine-like lines, implying the presence of an hyperbolic flux tube (HFT). The coronal region associated with the photospheric atoll configuration was distinctly identified in the form of a diffused dome-shaped bright structure directly observed in EUV images. A filament channel resided near the boundary of the atoll region. The activation and eruption of flux ropes from the filament channel led to the onset of four eruptive homologous quasi-circular ribbon flares within an interval of ≈11 hours. During the interval of the four flares, we observed continuous decay and cancellation of negative polarity flux within the atoll region. Accordingly, the apparent length of the HFT gradually reduced to a null-point-like configuration before the fourth flare. Prior to each flare, we observed localised brightening beneath the filaments which, together with flux cancellation, provided support for the tether-cutting model of solar eruption. The analysis of magnetic decay index revealed favourable conditions for the eruption, once the pre-activated flux ropes attained the critical heights for torus instability.

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Preflare Processes, Flux Rope Activation, Large-scale Eruption, and Associated X-class Flare from the Active Region NOAA 11875

Cited by 26 publications

References 122 publications

Observations of a prominence eruption and loop contraction

Observations of a prominence eruption and loop contraction

HXR emission from an activated flux rope and subsequent evolution of an eruptive long duration solar flare

Successive occurrences of quasi-circular ribbon flares in a fan-spine-like configuration involving hyperbolic flux tube

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