Relation Between the Coronal Mass Ejection Acceleration and the Non-Thermal Flare Characteristics

Berkebile-Stoiser, S.; Veronig, Astrid; Bein, B. M.; Temmer, Manuela

doi:10.1088/0004-637x/753/1/88

Cited by 45 publications

(38 citation statements)

References 44 publications

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“…Thus the distribution is slightly asymmetric with a few more events where CME acceleration appears to rise earlier than the rise of flare reconnection. This asymmetry is consistent with but less remarkable than that using the CME acceleration and the hard X-ray emission reported by Berkebile-Stoiser et al (2012). Fig.…”

Section: Start Times Of Cme Acceleration and Flare Reconnectionsupporting

confidence: 87%

How Does Magnetic Reconnection Drive the Early-stage Evolution of Coronal Mass Ejections?

Zhu

Qiu

Liewer

et al. 2020

ApJ

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Theoretically, CME kinematics are related to magnetic reconnection processes in the solar corona. However, the current quantitative understanding of this relationship is based on the analysis of only a handful of events. Here we report a statistical study of 60 CME-flare events from August 2010 to December 2013. We investigate kinematic properties of CMEs and magnetic reconnection in the low corona during the early phase of the eruptions, by combining limb observations from STEREO with simultaneous on-disk views from SDO. For a subset of 42 events with reconnection rate evaluated by the magnetic fluxes swept by the flare ribbons on the solar disk observed from SDO, we find a strong correlation between the peak CME acceleration and the peak reconnection rate. Also, the maximum velocities of relatively fast CMEs ( 600 km s −1 ) are positively correlated with the reconnection flux, but no such correlation is found for slow CMEs. A time-lagged correlation analysis suggests that the distribution of the time lag of CME acceleration relative to reconnection rate exhibits three peaks, approximately 10 minutes apart, and on average, acceleration-lead events have smaller reconnection rates. We further compare the CME total mechanical energy with the estimated energy in the current sheet. The comparison suggests that, for small-flare events, reconnection in the current sheet alone is insufficient to fuel CMEs. Results from this study suggest that flare reconnection may dominate

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Section: Start Times Of Cme Acceleration and Flare Reconnectionsupporting

confidence: 87%

How Does Magnetic Reconnection Drive the Early-stage Evolution of Coronal Mass Ejections?

Zhu

Qiu

Liewer

et al. 2020

ApJ

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“…In this respect it should be stressed that detailed inspection of graphs presented in these two studies again discloses that the acceleration starts before the flare impulsive phase, represented now directly by the HXR burst, and ends after it. Finally, Berkebile-Stoiser et al (2012) showed that the hardness of the flare HXR spectra is distinctly correlated with the CME acceleration. In most of the events, the CME acceleration started before the flare.…”

Section: Observational Aspectsmentioning

confidence: 95%

Solar eruptions: The CME‐flare relationship

Vršnak

2016

Astron Nachr

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Coronal mass ejections (CMEs), caused by large-scale eruptions of the coronal magnetic field, often are accompanied by a more localized energy release in the form of flares, as a result of dissipative magnetic-field reconfiguration. Morphology and evolution of such flares, also denoted as dynamical flares are often explained as a consequence of reconnection of the arcade magnetic field, taking place below the erupting magnetic flux rope. A close relationship of the CME acceleration and the flare energy release is evidenced by various statistical correlations between parameters describing CMEs and flares, as well as by the synchronization of the CME acceleration phase with the impulsive phase of the associated flare. Such behavior implies that there must be a feedback relation between the dynamics of the CME and the flare-associated reconnection process. From the theoretical standpoint, magnetic reconnection affects the CME dynamics in several ways. First, it reduces the tension of the overlying arcade magnetic field and increases the magnetic pressure below the flux rope, and in this way enhances the CME acceleration. Furthermore, it supplies the poloidal magnetic flux to the flux rope, which helps sustaining the electric current in the rope and prolonging the action of the driving Lorentz force to large distances. The role of these processes, directly relating solar flares and CMEs, is illustrated by employing a simple model, where the erupting structure is represented by a curved flux rope anchored at both sides in the dense/inert photosphere, being subject to the kink and torus instability. It is shown that in most strongly accelerated ejections, where values on the order of 10 km s −2 are attained, the poloidal flux supplied to the erupting rope has to be several times larger than was the initial flux.

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“…However, it has been shown that the acceleration profile of CMEs tends to peak during this period, too (cf. Zhang et al, 2001;Maričić et al, 2007;Temmer et al, 2008;Berkebile-Stoiser et al, 2012). Since coronal waves are highly associated with CMEs too (Section 5.2), timing alone cannot be used to make a distinction between a flare-related and a CME-related wave launch mechanism.…”

Section: Solar Flaresmentioning

confidence: 99%

Large-scale Globally Propagating Coronal Waves

Warmuth

2015

Living Rev. Sol. Phys.

156

140

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Large-scale, globally propagating wave-like disturbances have been observed in the solar chromosphere and by inference in the corona since the 1960s. However, detailed analysis of these phenomena has only been conducted since the late 1990s. This was prompted by the availability of high-cadence coronal imaging data from numerous spaced-based instruments, which routinely show spectacular globally propagating bright fronts. Coronal waves, as these perturbations are usually referred to, have now been observed in a wide range of spectral channels, yielding a wealth of information. Many findings have supported the "classical" interpretation of the disturbances: fast-mode MHD waves or shocks that are propagating in the solar corona. However, observations that seemed inconsistent with this picture have stimulated the development of alternative models in which "pseudo waves" are generated by magnetic reconfiguration in the framework of an expanding coronal mass ejection. This has resulted in a vigorous debate on the physical nature of these disturbances. This review focuses on demonstrating how the numerous observational findings of the last one and a half decades can be used to constrain our models of large-scale coronal waves, and how a coherent physical understanding of these disturbances is finally emerging. Article RevisionsLiving Reviews supports two ways of keeping its articles up-to-date:Fast-track revision. A fast-track revision provides the author with the opportunity to add short notices of current research results, trends and developments, or important publications to the article. A fast-track revision is refereed by the responsible subject editor. If an article has undergone a fast-track revision, a summary of changes will be listed here.Major update. A major update will include substantial changes and additions and is subject to full external refereeing. It is published with a new publication number.For detailed documentation of an article's evolution, please refer to the history document of the article's online version at http://dx

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Relation Between the Coronal Mass Ejection Acceleration and the Non-Thermal Flare Characteristics

Cited by 45 publications

References 44 publications

How Does Magnetic Reconnection Drive the Early-stage Evolution of Coronal Mass Ejections?

How Does Magnetic Reconnection Drive the Early-stage Evolution of Coronal Mass Ejections?

Solar eruptions: The CME‐flare relationship

Large-scale Globally Propagating Coronal Waves

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