Enhancing MHD model accuracy and CME forecasting by constraining coronal plasma properties with Faraday rotation

TL;DR

This study demonstrates how Faraday rotation measurements can improve the accuracy of MHD models and CME forecasts by constraining coronal plasma properties, validated through a detailed analysis of a 2012 CME event.

Contribution

The paper introduces a method to incorporate Faraday rotation data into MHD modeling, enhancing the prediction of CME shock parameters and magnetic field configurations.

Findings

Faraday rotation data constrains coronal magnetic field and electron density.

Adjusted MHD model parameters improve agreement with observational data.

Enhanced model accuracy aids in better CME forecasting.

Abstract

Faraday rotation measurements of extragalactic radio sources occulted by the solar corona serve as a powerful complementary tool for probing the pre-eruption electron density and magnetic field structure. These measurements thereby allow us to refine predictions from global MHD models. In this paper, we discuss our recent study of the morphological evolution of a CME-driven shock event that occurred on August 3, 2012. Our analysis used white-light coronagraphic observations from three different vantage points in space (SOHO and STEREO A and B). Obtaining data from these spacecraft, we derived key parameters such as the radius of curvature of the driving flux rope, the shock speed, and the standoff distance from the CMEs' leading edge. A notable feature of this event was the availability of rare Faraday rotation measurements of a group of extragalactic radio sources occulted by the solar corona, which were obtained a few hours before the eruption. These observations from the VLA radio interferometer provide independent information on the integrated product of the line-of-sight magnetic field component and electron density. By modeling the shock standoff distance and using constraints from the Faraday rotation measurements, we achieve a high level of agreement between the fast-mode Mach number predicted by the Magnetohydrodynamic Algorithm outside a Sphere (MAS) code in its thermodynamic mode and the value deduced from the analysis of the 3D reconstruction of coronagraphic data, provided that appropriate correction factors (f_b = 2.4 and f_n = 0.5) are applied in advance to scale the simulated magnetic field and electron density, respectively. Our results are consistent with previous estimates and provide critical information for fine-tuning future MHD simulations.