High-Energy Insights from an Escaping Coronal Mass Ejection with Solar Orbiter/STIX Observations

TL;DR

This study uses Solar Orbiter/STIX and EUV observations to analyze X-ray emissions from a highly occulted CME event, revealing insights into the energetic properties and altitude of the eruptive source.

Contribution

It presents a novel analysis combining STIX and EUI data to characterize X-ray emissions from an occulted CME, providing new insights into its energetic structure.

Findings

X-ray emissions originated from above 0.3 solar radii.

X-ray source showed a hot thermal component at 17 MK.

Extended X-ray source matched EUV emission and grew beyond STIX imaging limits.

Abstract

Solar eruptive events, including solar flares and coronal mass ejections (CMEs), are typically characterised by energetically significant X-ray emissions from flare-accelerated electrons and hot thermal plasmas. Occulted events, where the main flare is blocked by the solar limb, provide an opportunity to observe and analyse the X-ray emissions specifically associated with CMEs. This study investigates the X-ray and extreme ultraviolet (EUV) emissions associated with a large filament eruption and CME that occurred on February 15, 2022. This event was highly occulted from the three vantage points of Solar Orbiter, STEREO-A, and Earth. We utilised X-ray observations from the Spectrometer/Telescope for Imaging X-rays (STIX) and EUV observations from the Full Sun Imager (FSI) of the Extreme Ultraviolet Imager (EUI) on-board Solar Orbiter, supplemented by multi-viewpoint observations from STEREO-A/EUVI. This enabled a comprehensive analysis of the X-ray emissions in relation to the filament structure observed in EUV. We used STIX's imaging and spectroscopy capabilities to characterise the X-ray source associated with the eruption. Our analysis reveals that the X-ray emissions associated with the occulted eruption originated from an altitude exceeding 0.3Rsun above the main flare site. The X-ray time-profile showed a sharp increase and exponential decay, and consisted of both a hot thermal component at 17 MK and non-thermal emissions (>11.4 keV) characterised by an electron spectral index of 3.9. Imaging analysis showed an extended X-ray source that coincided with the EUV emission as observed from EUI, and was imaged until the source grew to a size larger than the imaging limit of STIX (180 arcsec). The findings demonstrate that STIX combined with EUI provides a unique and powerful tool for examining the energetic properties of the CME component of solar energetic eruptions.