Litcius/Paper detail

Physics-driven Machine Learning for the Prediction of Coronal Mass Ejections’ Travel Times

Sabrina Guastavino, Valentina Candiani, А. Бемпорад, Francesco Marchetti, Federico Benvenuto, Anna Maria Massone, Salvatore Mancuso, Roberto Susino, Daniele Telloni, Silvano Fineschi, Michele Piana

2023The Astrophysical Journal18 citationsDOIOpen Access PDF

Abstract

Abstract Coronal Mass Ejections (CMEs) correspond to dramatic expulsions of plasma and magnetic field from the solar corona into the heliosphere. CMEs are scientifically relevant because they are involved in the physical mechanisms characterizing the active Sun. However, more recently, CMEs have attracted attention for their impact on space weather, as they are correlated to geomagnetic storms and may induce the generation of solar energetic particle streams. In this space weather framework, the present paper introduces a physics-driven artificial intelligence (AI) approach to the prediction of CMEs’ travel time, in which the deterministic drag-based model is exploited to improve the training phase of a cascade of two neural networks fed with both remote sensing and in situ data. This study shows that the use of physical information in the AI architecture significantly improves both the accuracy and the robustness of the travel time prediction.

Topics & Concepts

Coronal mass ejectionPhysicsSpace weatherGeomagnetic stormCascadeSolar windHeliosphereAstronomyMagnetic fieldChromatographyQuantum mechanicsChemistrySolar and Space Plasma DynamicsSolar Radiation and PhotovoltaicsIonosphere and magnetosphere dynamics
Physics-driven Machine Learning for the Prediction of Coronal Mass Ejections’ Travel Times | Litcius