Coronal Magnetic Structure of Earthbound CMEs and In Situ Comparison

Palmerio, Erika; Kilpua, Emilia; Möstl, Christian; Bothmer, V.; James, Alexander W.; Green, Lucie M.; Isavnin, Alexey; Davies, J. A.; Harrison, R. A.

doi:10.1002/2017sw001767

Cited by 60 publications

(77 citation statements)

References 129 publications

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“…In order to further confirm the CME-ICME associations described above, we compare the helicity sign of the corresponding flux ropes at the Sun with the magnetic structures in situ. At the Sun, we use proxies from multiwavelength observations (e.g., Palmerio et al 2017Palmerio et al , 2018; at 1 AU, we apply the Gold-Hoyle flux rope fitting technique (Gold & Hoyle 1960;Farrugia et al 1999), shown in Figure 5 at both spacecraft. We note clear reverse-J flare ribbons after the eruption of both CME3 and CME4, which are a sign of negative helicity.…”

Section: Dst [Nt]mentioning

confidence: 99%

Multipoint Study of Successive Coronal Mass Ejections Driving Moderate Disturbances at 1 au

Palmerio

Scolini

Barnes

et al. 2019

ApJ

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We analyse in this work the propagation and geoeffectiveness of four successive coronal mass ejections (CMEs) that erupted from the Sun during 21-23 May 2013 and that were detected in interplanetary space by the Wind and/or STEREO-A spacecraft. All these CMEs featured critical aspects for understanding so-called "problem space weather storms" at Earth. In the first three events a limb CMEs resulted in moderately geoeffective in-situ structures at their target location in terms of the disturbance storm time (Dst) index (either measured or estimated). The fourth CME, which also caused a moderate geomagnetic response, erupted from close to the disc centre as seen from Earth, but it was not visible in coronagraph images from the spacecraft along the Sun-Earth line and appeared narrow and faint from off-angle viewpoints. Making the correct connection between CMEs at the Sun and their in-situ counterparts is often difficult for problem storms. We investigate these four CMEs using multiwavelength and multipoint remote-sensing observations (extreme ultraviolet, white light, and radio), aided by 3D heliospheric modelling, in order to follow their propagation in the corona and in interplanetary space and to assess their impact at 1 AU. Finally, we emphasise the difficulties in forecasting moderate space weather effects provoked by problematic and ambiguous events and the importance of multispacecraft data for observing and modelling problem storms.

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Section: Dst [Nt]mentioning

confidence: 99%

Multipoint Study of Successive Coronal Mass Ejections Driving Moderate Disturbances at 1 au

Palmerio

Scolini

Barnes

et al. 2019

ApJ

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“…The figure also shows the magnetic structure of the flux rope propagating towards the observer in the ecliptic plane-the configuration of most halo-CME eruptions that impact the Earth and cause significant geomagnetic responses (Zhang et al 2007). Understanding this connection between the preeruption magnetic configuration of the CME source region and the CME's structure and evolution during the eruption and propagation through the heliosphere is of critical importance to terrestrial space-weather forecasting (Palmerio et al 2018) and will play an increasingly important role in characterizing exoplanetary space weather (Airapetian et al 2016b;Cohen et al 2018). Figure 7 plots the evolution of the global magnetic energy (E M , black) and kinetic energy (E K , red).…”

Section: Carrington-scale Eruptive Stellar Flare and Cmementioning

confidence: 99%

Modeling a Carrington-scale Stellar Superflare and Coronal Mass Ejection from

Lynch

Airapetian

DeVore

et al. 2019

ApJ

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Observations from the Kepler mission have revealed frequent superflares on young and active solarlike stars. Superflares result from the large-scale restructuring of stellar magnetic fields, and are associated with the eruption of coronal material (a coronal mass ejection, or CME) and energy release that can be orders of magnitude greater than those observed in the largest solar flares. These catastrophic events, if frequent, can significantly impact the potential habitability of terrestrial exoplanets through atmospheric erosion or intense radiation exposure at the surface. We present results from numerical modeling designed to understand how an eruptive superflare from a young solar-type star, κ 1 Cet, could occur and would impact its astrospheric environment. Our data-inspired, three-dimensional magnetohydrodynamic modeling shows that global-scale shear concentrated near the radial-field polarity inversion line can energize the closed-field stellar corona sufficiently to power a global, eruptive superflare that releases approximately the same energy as the extreme 1859 Carrington event from the Sun. We examine proxy measures of synthetic emission during the flare and estimate the observational signatures of our CME-driven shock, both of which could have extreme space-weather impacts on the habitability of any Earth-like exoplanets. We also speculate that the observed 1986 Robinson-Bopp superflare from κ 1 Cet was perhaps as extreme for that star as the Carrington flare was for the Sun.

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“…The red line shows the shock and the interplanetary Coronal Mass Ejection flux rope is between the pair of blue lines. The schematic on right (from Palmerio et al, ) illustrates the local variations of the magnetic field around the axis of the flux rope.…”

Section: Coronal Mass Ejections Close To the Sun And In Interplanetarmentioning

confidence: 99%

“…While less dramatic, rotations and deflections in interplanetary space cannot be ignored. They can still change significantly the orientation and direction of the flux rope and for some cases even dominate the total change (e.g., Isavnin et al, ; Palmerio et al, ). For example, Good and Forsyth () reported a case where a flux rope rotated by several tens of degrees while it propagated from Mercury to radially aligned STEREO‐B near 1 AU.…”

Section: Physical Aspects Of Cmesmentioning

confidence: 99%

“…Several studies have investigated the relationship between solar surface properties and in situ behavior in order to derive the intrinsic magnetic characteristics of the CME flux rope through statistics (e.g., Bothmer & Schwenn, ; Palmerio et al, ; Patsourakos et al, ; Savani et al, ) or by case studies (e.g., Mandrini et al, ; Möstl et al, ; Palmerio et al, ; Temmer et al, ).…”

Section: Intrinsic Parameters Of Cmesmentioning

confidence: 99%

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Forecasting the Structure and Orientation of Earthbound Coronal Mass Ejections

et al. 2019

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Coronal Mass Ejections (CMEs) are the key drivers of strong to extreme space weather storms at the Earth that can have drastic consequences for technological systems in space and on ground. The ability of a CME to drive geomagnetic disturbances depends crucially on the magnetic structure of the embedded flux rope, which is thus essential to predict. The current capabilities in forecasting in advance (at least half a day before) the geoeffectiveness of a given CME is however severely hampered by the lack of remote-sensing measurements of the magnetic field in the corona and adequate tools to predict how CMEs deform, rotate, and deflect during their travel through the coronal and interplanetary space as they interact with the ambient solar wind and other CMEs. These problems can lead not only to overestimation or underestimation of the severity of a storm, but also to forecasting "misses" and "false alarms" that are particularly difficult for the end-users. In this paper, we discuss the current status and future challenges and prospects related to forecasting of the magnetic structure and orientation of CMEs. We focus both on observational-and modeling-based (first principle and semiempirical) approaches and discuss the space-and ground-based observations that would be the most optimal for making accurate space weather predictions. We also cover the gaps in our current understanding related to the formation and eruption of the CME flux rope and physical processes that govern its evolution in the variable ambient solar wind background that complicate the forecasting.

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Coronal Magnetic Structure of Earthbound CMEs and In Situ Comparison

Cited by 60 publications

References 129 publications

Multipoint Study of Successive Coronal Mass Ejections Driving Moderate Disturbances at 1 au

Multipoint Study of Successive Coronal Mass Ejections Driving Moderate Disturbances at 1 au

Modeling a Carrington-scale Stellar Superflare and Coronal Mass Ejection from

Forecasting the Structure and Orientation of Earthbound Coronal Mass Ejections

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