Rapid Buildup of a Magnetic Flux Rope during a Confined X2.2 Class Flare in NOAA AR 12673

Liu, Lijuan; Cheng, X.; Wang, Yuming; Zhou, Zhenjun; Guo, Yang; Cui, Jun

doi:10.3847/2041-8213/aae826

Cited by 52 publications

(59 citation statements)

References 50 publications

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“…it occurred without a CME eruption), while the other one was associated with a CME (e.g. Liu et al 2018;Zou et al 2019). This was a halo CME and had a plane-of-the-sky speed of approximately 1500 km s −1 .…”

Section: Introductionmentioning

confidence: 99%

“…This active region and its eruptions have been the subject of a number of studies (e.g. Yang et al 2017;Chertok et al 2018;Hou et al 2018;Inoue et al 2018;Liu et al 2018;Verma 2018;Yan et al 2018;Morosan et al 2019;Romano et al 2019;Zou et al 2019). During its transit across the solar disc, this AR produced four GOES X-class flares and numerous weaker flares.…”

Section: Introductionmentioning

confidence: 99%

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Time-dependent data-driven coronal simulations of AR 12673 from emergence to eruption

Price

Pomoell

Lumme

et al. 2019

A&A

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Aims. We present a detailed study of the magnetic evolution of AR 12673 using a magnetofrictional modelling approach. Methods. The fully data-driven and time-dependent model was driven with maps of the photospheric electric field, inverted from vector magnetogram observations obtained from the Helioseismic and Magnetic Imager (HMI) on board the Solar Dynamics Observatory (SDO). Our analysis was aided by studying the evolution of metrics such as the free magnetic energy and the current-carrying helicity budget of the domain, maps of the squashing factor and twist, and plots of the current density. These allowed us to better understand the dynamic nature of the magnetic topology. Results. Our simulation captured the time-dependent nature of the active region and the erupting flux rope associated with the X-class flares on 6 September 2017, including the largest of solar cycle 24. Additionally, our results suggest a possible threshold for eruptions in the ratio of current-carrying helicity to relative helicity. Conclusion. The flux rope was found to be a combination of two structures that partially combine during the eruption process. Our time-dependent data-driven magnetofrictional model is shown to be capable of generating magnetic fields consistent with extreme ultraviolet (EUV) observations.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Time-dependent data-driven coronal simulations of AR 12673 from emergence to eruption

Price

Pomoell

Lumme

et al. 2019

A&A

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“…On 2017 September 6, an X9.3 flare took place in AR 12673, which is the largest flare in Solar Cycle 24 (Yang et al 2017;Yan et al 2018;Liu et al 2018). Here we investigate the evolutions of this large flare and the associated complex magnetic system (see more details in Hou et al 2018).…”

Section: Observations and Resultsmentioning

confidence: 99%

“…By examining the AIA 304Å observations, we detected two sets of filament threads located in the AR core region before the occurrence of the X9.3 flare (see F1 and F2 in Fig. 1), which forms a double-decker MFR configuration (Liu et al 2012). Around 11:53:53 UT and 11:54:53 UT, brightenings appeared at the north and south cross sites of these two filament threads (also two MFRs, FR1 and FR2), implying the interaction between rising FR1 and FR2 (see green arrows in panels (a1)-(a2)).…”

Section: Observations and Resultsmentioning

confidence: 99%

Multi-flux-rope system in solar active regions

Hou

Zhang

et al. 2019

Proc. IAU

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Magnetic flux rope (MFR) is closely connected with solar eruptions, such as flares and coronal mass ejections. The classical scenario assumes a single MFR for each eruption, but it is reasonable to expect multiple MFRs in a complex active region (AR). Statistically investigating AR 11897, we verify the existence of multiple MFR proxies during the AR evolution. Recently, AR 12673 in 2017 September produced the two largest flares in Solar Cycle 24. The evolutions of the AR magnetic fields and the two large flares reveal that significant flux emergence and successive interactions between different emerging dipoles resulted in the formations of multiple MFRs and twisted loop bundles, which successively erupted like a chain reaction within several minutes before the peaks of the two flares. We propose that the eruptions of a multi-flux-rope system can rapidly release enormous magnetic energy and result in large flares in solar AR.

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“…This lower bound value of the twist is indicative of a weakly twisted, low‐lying, flux rope (Chintzoglou et al, ). In an alternate scenario, flux ropes can also be formed during strong, confined flares quickly leading up to a major CME within a short duration of time (Liu et al, ).…”

Section: Discussionmentioning

confidence: 99%

Investigation of a Confined C‐Class Flare in an Arch Filament System Close to a Regular Sunspot

Louis

2019

JGR Space Physics

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A moderate C1.1 class confined flare is investigated here, which occurred on 24 September 2013 at 22:56 UT, in an arch filament system close to a regular, unipolar sunspot. Spectropolarimetric observations from the Tenerife Infrared Polarimeter at the 70-cm German Vacuum Tower Telescope were combined with data from the Helioseismic Magnetic Imager and the Atmospheric Imaging Assembly to identify the processes that triggered the flare. The legs of this arch filament were anchored in the leading sunspot and the network flux region of opposite polarity. The flare was driven by small-scale, flux cancellation at the weak neutral line underlying the arch filament, which resulted in two small flaring events within an hour of the C1.1 flare. Flux cancellation was facilitated by the moat flow from the leading sunspot wherein small-scale magnetic fragments stream toward patches of preexisting flux. The cancellation of flux led to the destabilization of the arch filament, which was seen as an increase in the twist along the arch filament. The horizontal fields across the weak neutral line decay rapidly, which cannot prevent the filament from rising that results in a two-ribbon flare at the neutral line. The arch filament unwinds as it rises but is confined by the higher, overlying fields between the two polarities of the active region that decay much more slowly.Unlike PIL filaments, arch filament systems (AFSs) are a bunch of dark filament threads crossing the PIL and connecting the regions of opposite polarity, sometimes extending into sunspots (Bruzek, 1967;Weart & Zirin, 1969;Zwaan, 1985). The arches in the AFS exhibit an upward motion of about 10-15 km/s and downwflows of about 10-50 km/s along their legs. Flares occurring in AFS arise from reconnection with

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Rapid Buildup of a Magnetic Flux Rope during a Confined X2.2 Class Flare in NOAA AR 12673

Cited by 52 publications

References 50 publications

Time-dependent data-driven coronal simulations of AR 12673 from emergence to eruption

Time-dependent data-driven coronal simulations of AR 12673 from emergence to eruption

Multi-flux-rope system in solar active regions

Investigation of a Confined C‐Class Flare in an Arch Filament System Close to a Regular Sunspot

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