Asymmetric expansion of coronal mass ejections in the low corona

Cremades, H.; Iglesias, F. A.; Merenda, Luciano A.

doi:10.1051/0004-6361/201936664

Cited by 21 publications

(26 citation statements)

References 44 publications

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“…We find that for most of the CMEs, the width became constant in the height range of 2.5 − 3 R . This is in agreement with the results of Cremades et al (2020) who reported that the width of the CMEs changed considerably below 3 R . We also note from panel (b) that the mode of both the distributions fall in the overlapping height range of 2.5 − 3 R .…”

Section: Connecting Width To the 3d Kinematicssupporting

confidence: 93%

“…A sample of 460 CMEs observed by twin STEREO spacecrafts was used to compare the single-viewpoint and 3D kinematics (via triangulation) of CMEs in COR-2 FOV (Balmaceda et al 2018a). It is worth noting that although these studies provide 3D kinematic information, most of the analysis (Cremades et al (2020) and Cabello et al (2016) being exceptions in this context) are carried out starting from the COR-2 FOV, and hence the essential information in the inner corona is left out. Thus the major gap in our understanding of CME kinematics is to understand their 3D evolution in the inner corona.…”

Section: Introductionmentioning

confidence: 99%

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Connecting 3D Evolution of Coronal Mass Ejections to Their Source Regions

Majumdar

Pant

Patel

et al. 2020

ApJ

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Since Coronal Mass Ejections (CMEs) are the major drivers of space weather, it is crucial to study their evolution starting from the inner corona. In this work we use Graduated Cylindrical Shell (GCS) model to study the 3D evolution of 59 CMEs in the inner (< 3R ) and outer (> 3R ) corona using observations from COR-1 and COR-2 on-board Solar TErrestrial RElations Observatory (STEREO) spacecraft. We identify the source regions of these CMEs and classify them as CMEs associated with Active Regions (ARs), Active Prominences (APs), and Prominence Eruptions (PEs). We find 27 % of CMEs show true expansion and 31 % show true deflections as they propagate outwards. Using 3D kinematic profiles of CMEs, we connect the evolution of true acceleration with the evolution of true width in the inner and outer corona. Thereby providing the observational evidence for the influence of the Lorentz force on the kinematics to lie in the height range of 2.5 − 3 R . We find a broad range in the distribution of peak 3D speeds and accelerations ranging from 396 to 2465 km s −1 and 176 to 10922 m s −2 respectively with a long tail towards high values coming mainly from CMEs originating from ARs or APs. Further, we find the magnitude of true acceleration is be inversely correlated to its duration with a power law index of -1.19. We believe that these results will provide important inputs for the planning of upcoming space missions which will observe the inner corona and the models that study CME initiation and propagation.

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Section: Connecting Width To the 3d Kinematicssupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Connecting 3D Evolution of Coronal Mass Ejections to Their Source Regions

Majumdar

Pant

Patel

et al. 2020

ApJ

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“…(2015) also found that the flare‐related CME on 7 January 2014 changes its propagation direction by around 28° in latitude and 43° in longitude near the Sun attributing this to the “channeling” by the AR CMF rather than to deflection by nearby structures. In addition, besides the CME deflections, the ambient magnetic field configuration can effect the rotation and expansion of CMEs and lead to anisotropic expansion or deformation (i.e., Cremades et al., 2020; Kay et al., 2017; Zuccarello et al., 2012), which should be taken into consider and will be discussed in the future.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

The Deflection of Coronal Mass Ejections by the Ambient Coronal Magnetic Field Configuration

2020

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Solar coronal mass ejections (CMEs) are sometimes deflected during their propagation. This deflection may be the consequence of an interaction between the CME and the ambient coronal field, for example, a coronal hole, or the solar wind. The coronal magnetic field configuration is computed from daily synoptic maps of magnetic field from SOHO/MDI and SDO/HMI using a Potential Field Source Surface model. We analyze 30 halo‐CMEs whose deflection angle exceeds 90° by comparing the ambient magnetic field configuration and the measurement position angles of the CMEs. We find that the deflection of 87% of the CMEs (26 of 30) is consistent with the ambient magnetic field configuration, agreeing with previous studies. Of these 26, 69% are deflected toward the heliospheric current sheet, the boundary between the magnetic field polarities, and 31% toward a pseudo‐streamer, the boundary between same‐polarity magnetic field regions. This implies that the ambient coronal magnetic field configuration plays an important role in the deflection of CMEs and that the current sheet configuration is more important than a pseudo‐streamer. Of the 26 CMEs, the average and standard deviation of the minimum values of the deflection angle in three dimensions relative to an initially radial trajectory are 28° and 14°, respectively.

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“…Recently, it has been reported that the CMEs evolve non selfsimilarly in the inner corona (see Cremades et al, 2020;Majumdar et al, 2020). In the CDAW catalog, the width of a CME is defined as the maximum angle subtended by a CME on the center of the Sun when the CME enters the LASCO C3 field of view (FOV) where the width appears to approach a constant value (Gopalswamy, 2004).…”

Section: Width Distribution Of Cmesmentioning

confidence: 99%

“…Apart from their radial propagation, CMEs are also known to exhibit lateral expansion that leads to an increase in their angular width as they propagate outwards (Kay et al, 2015;Cremades et al, 2020;Majumdar et al, 2020) and that it is the Lorentz force at their source region that is closely responsible for translating and expanding them (Subramanian et al, 2014). In this regard, Zhao et al (2017) reported on the importance of the angular width of a CME, in determining whether the corresponding interplanetary CME and the preceding shock will reach Earth.…”

Section: Introductionmentioning

confidence: 99%

Investigating Width Distribution of Slow and Fast CMEs in Solar Cycles 23 and 24

Pant

Majumdar

Patel

et al. 2021

Front. Astron. Space Sci.

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Coronal Mass Ejections (CMEs) are highly dynamic events originating in the solar atmosphere, that show a wide range of kinematic properties and are the major drivers of the space weather. The angular width of the CMEs is a crucial parameter in the study of their kinematics. The fact that whether slow and fast CMEs (as based on their relative speed to the average solar wind speed) are associated with different processes at the location of their ejection is still debatable. Thus, in this study, we investigate their angular width to understand the differences between the slow and fast CMEs. We study the width distribution of slow and fast CMEs and find that they follow different power law distributions, with a power law indices (α) of –1.1 and –3.7 for fast and slow CMEs respectively. To reduce the projection effects, we further restrict our analysis to only limb events as derived from manual catalog and we find similar results. We then associate the slow and fast CMEs to their source regions, and classified the sources as Active Regions (ARs) and Prominence Eruptions. We find that slow and fast CMEs coming from ARs and PEs, also follow different power laws in their width distributions. This clearly hints toward a possibility that different mechanisms might be involved in the width expansion of slow and fast CMEs coming from different sources.These results are also crucial from the space weather perspective since the width of the CME is an important factor in that aspect.

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Asymmetric expansion of coronal mass ejections in the low corona

Cited by 21 publications

References 44 publications

Connecting 3D Evolution of Coronal Mass Ejections to Their Source Regions

Connecting 3D Evolution of Coronal Mass Ejections to Their Source Regions

The Deflection of Coronal Mass Ejections by the Ambient Coronal Magnetic Field Configuration

Investigating Width Distribution of Slow and Fast CMEs in Solar Cycles 23 and 24

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