IAFE   05512
INSTITUTO DE ASTRONOMIA Y FISICA DEL ESPACIO
Unidad Ejecutora - UE
congresos y reuniones científicas
Título:
Three-Dimensional Tomographic Reconstruction and MHD Modeling of WHPI target rotations CR-2219 and CR-2223
Autor/es:
FEDERICO A. NUEVO; BARTHOLOMEUS VAN DER HOLST; JULIEN WOJAK; FEDERICO A. NUEVO; BARTHOLOMEUS VAN DER HOLST; JULIEN WOJAK; DIEGO G. LLOVERAS; NISHTHA SACHDEVA; RICHARD A. FRAZIN; DIEGO G. LLOVERAS; NISHTHA SACHDEVA; RICHARD A. FRAZIN; ALBERTO M. VASQUEZ; WARD B. MANCHESTER IV; PHILIPPE LAMY; ALBERTO M. VASQUEZ; WARD B. MANCHESTER IV; PHILIPPE LAMY
Reunión:
Conferencia; American Geophysical Union Fall Meeting; 2020
Institución organizadora:
American Geophysical Union
Resumen:
Accurate prediction of space weather conditions requires state-of-the-art three-dimensional(3D) magnetohydrodynamic (MHD) models, which need to be validated with observational data. The recent deep minimum of solar activity, between solar cycles 24 and 25, renews the opportunity to study the Sun-Earth connection under the simplest solar and space environmental conditions. The international Whole Heliosphere and Planetary Interactions (WHPI) initiative aims at this speci c purpose. In this work, we study two WHPI campaign periods, the July 2019 total solar eclipse Carrington rotation (CR)-2019, and the Parker Solar Probe and STEREO-A closest approach CR-2223. Based on narrowband EUV data provided by the SDO/AIA instrument we carry out tomographic reconstruction of the coronal electron density and temperature in the range of heliocentric heights r ≤ 1.25 R sun . Based on visible light coronagraph data provided by the SoHO/LASCO-C2 instrument we carry out tomographic reconstruction of the coronal electron density and in the range of heliocentric heights ≈ 2.5- 6.0 R sun . Applying ADAPT-GONG synoptic magnetograms as boundary conditions, we use the Alfven Wave Solar Model (AWSoM) to simulate the corona and solar wind for these time periods. We study the capability of the 3D-MHD model to reproduce the tomographic reconstructions in both closed and open coronal magnetic structures. In coronal holes in particular, we investigate the correlation between the reconstructed 3D distribution of the thermodynamical properties in the low corona and the 3D distribution of the physical parameters of the terminal solar wind of the model, discriminating its fast and slow components.