Relationship between prominence eruptions and coronal mass ejections during solar cycle 24

TL;DR

This study analyzes the relationship between prominence eruptions and coronal mass ejections during solar cycle 24, revealing their association rates, morphological features, and how their dynamics vary with the solar cycle.

Contribution

It provides a comprehensive analysis of prominence eruptions and CMEs, including their association, speeds, and evolution, during solar cycle 24, highlighting their morphological and temporal relationships.

Findings

54% of prominence eruptions are associated with CMEs.

CME cores have higher speeds (~390 km/s) than PEs (~62 km/s).

Prominences evolve into CME cores at higher altitudes.

Abstract

In this article, we present the relationship between prominence eruptions (PEs) and coronal mass ejections (CMEs) from May 2010 to December 2019 covering most of solar cycle 24. We used data from the Atmospheric Imaging Assembly (AIA) for PEs and the Large Angle and Spectrometric Coronagraph (LASCO) for CMEs. We identified 1225 PEs, with 67% being radial, 32% transverse, and 1% failed PEs. The radial, transverse PEs, and the combined set have average speeds of ~53, 9, and 38 km/s, respectively. The PE association with CMEs is examined by assigning a confidence level (CL) from 0 (no association) to 3 (clear association). Out of 1225 PEs, 662 (54%) are found to be associated to CMEs including CL 1, 2, and 3. Our study reveals that the spatial and temporal relationships between PEs and CMEs vary over the solar cycle. During solar minima, CMEs tend to deflect towards the equator, possibly due to a stronger polar field. Temporal offsets are larger during solar maxima and smaller during the minima. This implies that the PEs appear in LASCO C2 FOV earlier during the minima than during the maxima. Among the 662 CMEs associated with PEs, 78% show clear bright core structures. Investigation of the morphological and temporal behavior of these CMEs indicate that the prominences evolves into CME cores at higher altitudes suggesting that PEs and CME cores are the same structure. The average speeds of the PEs, CME core, and CME leading edge are 62, 390, and 525 km/s, respectively. The speed of CME cores are more than the speed of PEs because the former are observed at larger heights where they have accelerated to higher speeds.