Abstract:We investigate here the magnetic properties of a large-scale magnetic flux rope related to a coronal mass ejection (CME) that erupted from the Sun on September 12, 2014 and produced a well-defined flux rope in interplanetary space on September 14–15, 2014. We apply a fully data-driven and time-dependent magnetofrictional method (TMFM) using Solar Dynamics Observatory (SDO) magnetograms as the lower boundary condition. The simulation self-consistently produces a coherent flux rope and its ejection from the simu… Show more
“…In addition, the current density distribution in Figure 10f at the intersections of a vertical slice with two field line bundles also shows less clearly-defined concentrations in those field-line regions. So different from the NLFFF extrapolation result by Zhao et al (2016) and the time-dependent magnetofrictional modeling result by Kilpua et al (2021), which demonstrated the existence of a strongly twisted MFR, we do not produce such a pre-existing MFR prior to the flare eruption for event 2.…”
Section: Results For Ar 12158contrasting
confidence: 99%
“…The CMEs associated with the corresponding flares in these two events have been both observed by SOHO and STEREO spacecraft close to the peak times of the corresponding flares (Vemareddy & Zhang 2014;Cheng et al 2015;Cheng & Ding 2016;Joshi et al 2017). And the associated ICME/MC events were also observed by the WIND and ACE spacecraft at 1 au, which have been reported by Hu et al (2021a) and Kilpua et al (2021), respectively.…”
Section: Events Overviewmentioning
confidence: 54%
“…There was also a halo CME following the flare based on the observations from SOHO/LASCO and the coronagraph of STEREO B (data from STEREO A was unavailable during event 2). After two days, the WIND spacecraft encountered the subsequent ICME/MC structure at Earth (Kilpua et al 2021). Therefore, the connections of CME-MFRs from the Sun to Earth are well established for these two events.…”
In order to bridge the gap between heliospheric and solar observations of coronal mass ejections (CMEs), one of the key steps is to improve the understanding of their corresponding magnetic structures like the magnetic flux ropes (MFRs). But it remains a challenge to confirm the existence of a coherent MFR before or upon the CME eruption on the Sun and to quantitatively characterize the CME-MFR due to the lack of direct magnetic field measurement in the corona. In this study, we investigate the MFR structures, originating from two active regions (ARs), AR 11719 and AR 12158, and estimate their magnetic properties quantitatively. We perform the nonlinear force-free field extrapolations with preprocessed photospheric vector magnetograms. In addition, remote-sensing observations are employed to find indirect evidence of MFRs on the Sun and to analyze the time evolution of magnetic reconnection flux associated with the flare ribbons during the eruption. A coherent "pre-existing" MFR structure prior to the flare eruption is identified quantitatively for one event from the combined analysis of the extrapolation and observation. Then the characteristics of MFRs for two events on the Sun before and during the eruption, forming the CME-MFR, including the axial
“…In addition, the current density distribution in Figure 10f at the intersections of a vertical slice with two field line bundles also shows less clearly-defined concentrations in those field-line regions. So different from the NLFFF extrapolation result by Zhao et al (2016) and the time-dependent magnetofrictional modeling result by Kilpua et al (2021), which demonstrated the existence of a strongly twisted MFR, we do not produce such a pre-existing MFR prior to the flare eruption for event 2.…”
Section: Results For Ar 12158contrasting
confidence: 99%
“…The CMEs associated with the corresponding flares in these two events have been both observed by SOHO and STEREO spacecraft close to the peak times of the corresponding flares (Vemareddy & Zhang 2014;Cheng et al 2015;Cheng & Ding 2016;Joshi et al 2017). And the associated ICME/MC events were also observed by the WIND and ACE spacecraft at 1 au, which have been reported by Hu et al (2021a) and Kilpua et al (2021), respectively.…”
Section: Events Overviewmentioning
confidence: 54%
“…There was also a halo CME following the flare based on the observations from SOHO/LASCO and the coronagraph of STEREO B (data from STEREO A was unavailable during event 2). After two days, the WIND spacecraft encountered the subsequent ICME/MC structure at Earth (Kilpua et al 2021). Therefore, the connections of CME-MFRs from the Sun to Earth are well established for these two events.…”
In order to bridge the gap between heliospheric and solar observations of coronal mass ejections (CMEs), one of the key steps is to improve the understanding of their corresponding magnetic structures like the magnetic flux ropes (MFRs). But it remains a challenge to confirm the existence of a coherent MFR before or upon the CME eruption on the Sun and to quantitatively characterize the CME-MFR due to the lack of direct magnetic field measurement in the corona. In this study, we investigate the MFR structures, originating from two active regions (ARs), AR 11719 and AR 12158, and estimate their magnetic properties quantitatively. We perform the nonlinear force-free field extrapolations with preprocessed photospheric vector magnetograms. In addition, remote-sensing observations are employed to find indirect evidence of MFRs on the Sun and to analyze the time evolution of magnetic reconnection flux associated with the flare ribbons during the eruption. A coherent "pre-existing" MFR structure prior to the flare eruption is identified quantitatively for one event from the combined analysis of the extrapolation and observation. Then the characteristics of MFRs for two events on the Sun before and during the eruption, forming the CME-MFR, including the axial
“…All current data-driven models can be classified mainly into three groups with increasing degrees of complexity and, thus, realism. They are the magnetofrictional model, 22 , 23 , 24 , 25 , 26 , 27 , 28 , 29 , 30 , 31 , 32 , 33 the zero-β MHD model, 34 , 35 , 36 , 37 , 38 , 39 and the full MHD model. 40 , 41 , 42 , 43 , 44 , 45 , 46 , 47 , 48 , 49 , 50 The full MHD model can be divided into subclasses, such as isothermal, ideal, resistive, and full thermodynamic (including radiation and thermal conduction) models according to the different types of energy equations.…”
Section: Different Modelsmentioning
confidence: 99%
“…Kilpua et al. 25 analyzed the details of an MFR eruption in AR NOAA 12158 and attempted to compare its structure (but still in the source region) with in situ observations at 1 AU. Figure 2 Synthetic images of coronal loops based on current density distribution from a data-driven magnetofrictional model for the evolution of AR NOAA 11158 (A–C) The same data from different viewing angles.…”
Section: Data-driven Modeling Of the Slow Evolution Of Coronal Magnet...mentioning
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
