Future capabilities of CME polarimetric 3D reconstructions with the METIS instrument: A numerical test

TL;DR

This study assesses the accuracy of the polarization ratio technique in determining the 3D structure, direction, and density of CMEs using simulated METIS coronagraph images, providing insights for upcoming solar observations.

Contribution

It introduces a method to evaluate and improve the polarization ratio technique for 3D CME reconstruction using synthetic data from MHD simulations.

Findings

High accuracy in locating CME center of mass along the line of sight.

The polarization ratio technique effectively determines CME propagation direction.

The combined use of polarization ratio and white-light images reduces density estimation errors.

Abstract

Understanding the 3D structure of coronal mass ejections (CMEs) is crucial for understanding the nature and origin of solar eruptions. To derive information on the 3D structure of CMEs from white-light (total and polarized brightness) images, the polarization ratio technique is widely used. The soon-to-be-launched METIS coronagraph on board Solar Orbiter will use this technique to produce new polarimetric images. We determine the accuracy at which the position of the centre of mass, direction and speed of propagation, and the column density of the CME can be determined along the line of sight. We perform a 3D MHD simulation of a flux rope ejection where a CME is produced. From the simulation we (i) synthesize the corresponding METIS white-light (total and polarized brightness) images and (ii) apply the polarization ratio technique to these synthesized images and compare the results with the known density distribution from the MHD simulation. We find that the polarization ratio technique reproduces with high accuracy the position of the centre of mass along the line of sight. However, some errors are inherently associated with this determination. The polarization ratio technique also allows information to be derived on the real 3D direction of propagation of the CME. In addition, we find that the column density derived from white-light images is accurate and we propose an improved technique where the combined use of the polarization ratio technique and white-light images minimizes the error in the estimation of column densities. Our method allows us to thoroughly test the performance of the polarization ratio technique and allows a determination of the errors associated with it, which means that it can be used to quantify the results from the analysis of the forthcoming METIS observations in white light (total and polarized brightness).