Your search keyword '"Palmerio, Erika"' showing total 4 results

1. The effect of the ambient solar wind medium on a CME-driven shock and the associated gradual solar energetic particle event

Author

National Aeronautics and Space Administration (US), Research Foundation - Flanders, Science and Technology Facilities Council (UK), European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Space Agency, Wijsen, Nicolas, Lario, David, Sánchez-Cano, Beatriz, Jebaraj, Immanuel C., Dresing, Nina, Richardson, Ian, Aran, Angels, Kouloumvakos, Athanasios, Ding, Zhejie, Niemela, Antonio, Palmerio, Erika, Carcaboso, Fernando, Vainio, Rami, Afanasiev, Alexandr, Pinto, Marco, Pacheco, Daniel, Poedts, Stefaan, Heyner, Daniel, National Aeronautics and Space Administration (US), Research Foundation - Flanders, Science and Technology Facilities Council (UK), European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Space Agency, Wijsen, Nicolas, Lario, David, Sánchez-Cano, Beatriz, Jebaraj, Immanuel C., Dresing, Nina, Richardson, Ian, Aran, Angels, Kouloumvakos, Athanasios, Ding, Zhejie, Niemela, Antonio, Palmerio, Erika, Carcaboso, Fernando, Vainio, Rami, Afanasiev, Alexandr, Pinto, Marco, Pacheco, Daniel, Poedts, Stefaan, and Heyner, Daniel

Abstract

We present simulation results of a gradual solar energetic particle (SEP) event detected on 2021 October 9 by multiple spacecraft, including BepiColombo (Bepi) and near-Earth spacecraft such as the Advanced Composition Explorer (ACE). A peculiarity of this event is that the presence of a high-speed stream (HSS) affected the low-energy ion component (≲5 MeV) of the gradual SEP event at both Bepi and ACE, despite the HSS having only a modest solar wind speed increase. Using the EUHFORIA (European Heliospheric FORecasting Information Asset) magnetohydrodynamic model, we replicate the solar wind during the event and the coronal mass ejection (CME) that generated it. We then combine these results with the energetic particle transport model PARADISE (PArticle Radiation Asset Directed at Interplanetary Space Exploration). We find that the structure of the CME-driven shock was affected by the nonuniform solar wind, especially near the HSS, resulting in a shock wave front with strong variations in its properties such as its compression ratio and obliquity. By scaling the emission of energetic particles from the shock to the solar wind compression at the shock, an excellent match between the PARADISE simulation and in situ measurements of ≲5 MeV ions is obtained. Our modeling shows that the intricate intensity variations observed at both ACE and Bepi were influenced by the nonuniform emission of energetic particles from the deformed shock wave and demonstrates the influence of even modest background solar wind structures on the development of SEP events.

Published

2023

2. Deflection of Coronal Mass Ejections in Unipolar Ambient Magnetic Fields.

Author

Ben-Nun, Michal, Török, Tibor, Palmerio, Erika, Downs, Cooper, Titov, Viacheslav S., Linton, Mark G., Caplan, Ronald M., and Lionello, Roberto

Subjects

CORONAL mass ejections, MAGNETIC fields, SOLAR corona, MAGNETIC flux, ELECTRIC currents

Abstract

The trajectories of coronal mass ejections (CMEs) are often seen to deviate substantially from a purely radial propagation direction. Such deviations occur predominantly in the corona and have been attributed to "channeling" or deflection of the eruptive flux by asymmetric ambient magnetic fields. Here, we investigate an additional mechanism that does not require any asymmetry of the preeruptive ambient field. Using magnetohydrodynamic numerical simulations, we show that the trajectories of CMEs through the solar corona can significantly deviate from the radial direction when propagation takes place in a unipolar radial field. We demonstrate that the deviation is most prominent below ∼15 R ⊙ and can be attributed to an "effective I × B force" that arises from the intrusion of a magnetic flux rope with a net axial electric current into a unipolar background field. These results are important for predictions of CME trajectories in the context of space-weather forecasts, as well as for reaching a deeper understanding of the fundamental physics underlying CME interactions with the ambient fields in the extended solar corona. [ABSTRACT FROM AUTHOR]

Published

2023

3. Predicting the Magnetic Fields of a Stealth CME Detected by Parker Solar Probe at 0.5 au.

Author

Palmerio, Erika, Kay, Christina, Al-Haddad, Nada, Lynch, Benjamin J., Yu, Wenyuan, Stevens, Michael L., Pal, Sanchita, and Lee, Christina O.

Subjects

*MAGNETIC fields, *INTERPLANETARY magnetic fields, *SUN, *CORONAL mass ejections, *SOLAR corona, *INFORMATION modeling, *AIDS to navigation

Abstract

Stealth coronal mass ejections (CMEs) are eruptions from the Sun that are not associated with appreciable low-coronal signatures. Because they often cannot be linked to a well-defined source region on the Sun, analysis of their initial magnetic configuration and eruption dynamics is particularly problematic. In this article, we address this issue by undertaking the first attempt at predicting the magnetic fields of a stealth CME that erupted in 2020 June from the Earth-facing Sun. We estimate its source region with the aid of off-limb observations from a secondary viewpoint and photospheric magnetic field extrapolations. We then employ the Open Solar Physics Rapid Ensemble Information modeling suite to evaluate its early evolution and forward model its magnetic fields up to Parker Solar Probe, which detected the CME in situ at a heliocentric distance of 0.5 au. We compare our hindcast prediction with in situ measurements and a set of flux-rope reconstructions, obtaining encouraging agreement on arrival time, spacecraft-crossing location, and magnetic field profiles. This work represents a first step toward reliable understanding and forecasting of the magnetic configuration of stealth CMEs and slow streamer-blowout events. [ABSTRACT FROM AUTHOR]

Published

2021

4. Modeling a Coronal Mass Ejection from an Extended Filament Channel. I. Eruption and Early Evolution.

Author

Lynch, Benjamin J., Palmerio, Erika, DeVore, C. Richard, Kazachenko, Maria D., Dahlin, Joel T., Pomoell, Jens, and Kilpua, Emilia K. J.

Subjects

*CORONAL mass ejections, *SOLAR corona, *SOLAR flares, *FIBERS, *HELIOSEISMOLOGY, *MAGNETIC storms, *UMPOLUNG, *MAGNETIC fields

Abstract

We present observations and modeling of the magnetic field configuration, morphology, and dynamics of a large-scale, high-latitude filament eruption observed by the Solar Dynamics Observatory. We analyze the 2015 July 9–10 filament eruption and the evolution of the resulting coronal mass ejection (CME) through the solar corona. The slow streamer-blowout CME leaves behind an elongated post-eruption arcade above the extended polarity inversion line that is only poorly visible in extreme ultraviolet (EUV) disk observations and does not resemble a typical bright flare-loop system. Magnetohydrodynamic (MHD) simulation results from our data-inspired modeling of this eruption compare favorably with the EUV and white-light coronagraph observations. We estimate the reconnection flux from the simulation's flare-arcade growth and examine the magnetic-field orientation and evolution of the erupting prominence, highlighting the transition from an erupting sheared-arcade filament channel into a streamer-blowout flux-rope CME. Our results represent the first numerical modeling of a global-scale filament eruption where multiple ambiguous and complex observational signatures in EUV and white light can be fully understood and explained with the MHD simulation. In this context, our findings also suggest that the so-called stealth CME classification, as a driver of unexpected or "problem" geomagnetic storms, belongs more to a continuum of observable/nonobservable signatures than to separate or distinct eruption processes. [ABSTRACT FROM AUTHOR]

Published

2021