Hydrodynamic Simulation of a nano-flare heated multi-strand solar atmospheric loop

TL;DR

This study models a solar atmospheric loop as multiple strands heated by nano-flares, revealing how different energy distributions influence the loop's thermal structure and observable features.

Contribution

It introduces a multi-strand hydrodynamic simulation with a power-law energy input distribution, providing insights into the thermal and dynamic behavior of nano-flare heated solar loops.

Findings

Higher alpha increases apex temperature and reduces temperature variation.

Cool plasma blobs travel along strands, affecting observed emission.

Loop structure depends on energy input distribution and number of strands.

Abstract

There is a growing body of evidence that the plasma loops seen with current instrumentation (SOHO, TRACE and Hinode) may consist of many sub-resolution elements or strands. Thus, the overall plasma evolution we observe in these features could be the cumulative result of numerous individual strands undergoing sporadic heating. This paper presents a short (10^9 cm ~ 10 Mm) ``global loop'' as 125 individual strands where each strand is modelled independently by a one-dimensional hydrodynamic simulation. The energy release mechanism across the strands consists of localised, discrete heating events (nano-flares). The strands are ``coupled'' together through the frequency distribution of the total energy input to the loop which follows a power law distribution with index alpha. The location and lifetime of each energy event occurring is random. Although a typical strand can go through a series of well-defined heating/cooling cycles, when the strands are combined, the overall quasi-static emission measure weighted thermal profile for the global loop reproduces a hot apex/cool base structure. Localised cool plasma blobs are seen to travel along individual strands which could cause the loop to `disappear' from coronal emission and appear in transition or chromospheric ones. As alpha increases (from 0 to 2.29 to 3.29), more weight is given to the smallest heating episodes. Consequently, the overall global loop apex temperature increases while the variation of the temperature around that value decreases. Any further increase in alpha saturates the loop apex temperature variations at the current simulation resolution. The effect of increasing the number of strands and the loop length as well as the implications of these results upon possible future observing campaigns for TRACE and Hinode are discussed.