Investigating the response of loop plasma to nanoflare heating using RADYN simulations

TL;DR

This study uses 1D hydrodynamic simulations to analyze how coronal loops respond to nanoflares caused by thermal or non-thermal electron heating, comparing results with IRIS and AIA observations to understand energy deposition and plasma dynamics.

Contribution

It provides new insights into how non-thermal electron beams with high low-energy cutoff values influence transition region responses, and constrains heating event energies and electron densities.

Findings

High E_C beams cause blueshifts in IRIS Si IV lines, not thermal conduction.

Loop plasma response depends on initial electron density, affecting observability.

Coronal emission from single strands is below detection threshold, requiring multiple strands.

Abstract

We present the results of 1D hydrodynamic simulations of coronal loops which are subject to nanoflares, caused by either in-situ thermal heating, or non-thermal electrons (NTE) beams. The synthesized intensity and Doppler shifts can be directly compared with IRIS and AIA observations of rapid variability in the transition region (TR) of coronal loops, associated with transient coronal heating. We find that NTE with high enough low-energy cutoff (E$_\textrm{C}$) deposit energy in the lower TR and chromosphere causing blueshifts (up to~$\sim$~20 km/s) in the \emph{IRIS} \siiv~lines, which thermal conduction cannot reproduce. The E$_\textrm{C}$ threshold value for the blueshifts depends on the total energy of the events ($\approx$~5 keV for 10$^{24}$ ergs, up to 15 keV for 10$^{25}$ ergs). The observed footpoint emission intensity and flows, combined with the simulations, can provide constraints on both the energy of the heating event and E$_\textrm{C}$. The response of the loop plasma to nanoflares depends crucially on the electron density: significant \siiv~intensity enhancements and flows are observed only for initially low-density loops ($<$~10$^{9}$~cm$^{-3}$). This provides a possible explanation of the relative scarcity of observations of significant moss variability. While the TR response to single heating episodes can be clearly observed, the predicted coronal emission (AIA 94\AA) for single strands is below current detectability, and can only be observed when several strands are heated closely in time. Finally, we show that the analysis of the IRIS \mgii~chromospheric lines can help further constrain the properties of the heating mechanisms.