Temporal variations of X-ray solar flare loops: length, corpulence, position, temperature, plasma pressure and spectra

TL;DR

This study analyzes the temporal evolution of X-ray solar flare loops, revealing phases of contraction and expansion in loop size, and providing new insights into plasma heating, density, and magnetic field behavior during flares.

Contribution

First detailed analysis of temporal changes in X-ray loop lengths and widths, linking plasma properties with magnetic field dynamics during solar flares.

Findings

Loop length and volume decrease before X-ray peak

Number density and thermal pressure increase during flare

Post-peak, loop volume and width increase, indicating expansion

Abstract

The spatial and spectral properties of three solar flare coronal X-ray loops are studied before, during and after the peak X-ray emission. Using observations from the Ramaty High Energy Solar Spectroscopic Imager (RHESSI), we deduce the temporal changes in emitting X-ray length, corpulence, volume, position, number density and thermal pressure. We observe a decrease in the loop length, width and volume before the X-ray peak, and an increasing number density and thermal pressure. After the X-ray peak, volume increases and loop corpulence grows due to an increasing width. The volume variations are more pronounced than the position variations, often known as magnetic line contraction. We believe this is the first dedicated study of the temporal evolution of X-ray loop lengths and widths. Collectively, the observations also show for the first time three temporal phases given by peaks in temperature, X-ray emission and thermal pressure, with minimum volume coinciding with the X-ray peak. Although the volume of the flaring plasma decreases before the peak in X-ray emission, the relationship between temperature and volume does not support simple compressive heating in a collapsing magnetic trap model. Within a low beta plasma, shrinking loop widths perpendicular to the guiding field can be explained by squeezing the magnetic field threading the region. Plasma heating leads to chromospheric evaporation and growing number density, producing increasing thermal pressure and decreasing loop lengths as electrons interact at shorter distances and we believe after the X-ray peak, the increasing loop corpulence.