Early Evolution of Earth-Directed Coronal Mass Ejections in the Vicinity of Coronal Holes

TL;DR

This study analyzes how coronal holes influence the early deflection and rotation of Earth-directed CMEs, highlighting the significance of CHs and CME velocity in their trajectory changes.

Contribution

It provides quantitative evidence of the impact of coronal hole magnetic fields on CME deflection and rotation in the low corona.

Findings

CHIP force significantly influences CME direction change in the low corona.

Higher CME velocities are associated with lower deflection rates.

CH influence diminishes as CMEs propagate outward.

Abstract

We investigate the deflection and rotation behavior of 49 Earth-directed coronal mass ejections (CMEs) spanning the period from 2010 to 2020 aiming to understand the potential influence of coronal holes (CHs) on their trajectories. We perform the GCS reconstruction in multiple time steps and we consider the difference in the longitude, latitude, and inclination between the first and last GCS reconstructions as possible signatures of deflection/rotation. Furthermore, we examine the presence of nearby CHs at the time of eruption and employ the Collection of Analysis Tools for Coronal Holes (CATCH) to estimate relevant CH parameters. To assess the potential influence of CHs on the deflection and rotation of CMEs, we calculate the Coronal Hole Influence Parameter (CHIP) for each event and analyse its relationship with their trajectories. A statistically significant difference is observed between CHIP force and the overall change in a CME's direction in the lower corona. The overall change in a CME's direction accounts cumulatively for the change in latitude, longitude, and rotation. This suggests that the CHIP force in the low corona has a significant influence on the overall change in the direction of Earth-directed CMEs. However, as the CME evolves outward, the CHIP force becomes less effective in causing deflection or rotation at greater distances. Additionally, we observe a negative correlation between the deflection rate of the CMEs and their velocity, suggesting that higher velocities are associated with lower deflection rates. Hence, the velocity of a CME, along with the magnetic-field from CHs, appears to play a significant role in the deflection of CMEs.