Prominence and coronal rain formation by steady versus stochastic heating and how we can relate it to observations

TL;DR

This study compares prominence formation via steady and stochastic heating using 2.5D simulations, revealing distinct structural and dynamic differences that can inform observational interpretations of coronal rain and prominences.

Contribution

It demonstrates how different heating mechanisms produce distinct prominence structures and dynamics, linking simulation results with potential observational signatures.

Findings

Steady heating leads to vertically structured, static prominences.

Stochastic heating results in dynamic, horizontally oriented threads.

Reconnection activity varies significantly between heating types.

Abstract

Prominences and coronal rain are two forms of coronal condensations for which we still lack satisfactory details on the formation pathways and conditions under which the two come to exist. We compared prominences that formed via a steady versus stochastic type of heating. We performed 2.5D simulations using the open-source MPI-AMRVAC code. To further extend the work and allow for future direct comparison with observations, we used Lightweaver to form spectra of the filament view of our steady case prominence. With that, we analysed a reconnection event that shares certain characteristics with nanojets. We show how different forms of localised heating that induce thermal instability result in prominences with different properties. The steady form of heating results in prominence with a clear vertical structure stretching across the magnetic field lines. On the other hand, stochastic heating produces many threads that predominantly have a horizontal motion along the field lines. In the steady heating case, the prominence is relatively static; however, there is evidence of reconnection happening almost the entire time the prominence is present. In the case of stochastic heating, the threads are highly dynamic, with them also exhibiting a form of transverse oscillation (strongly resembling the decayless type). The fact that the threads in the stochastic heating case are constantly moving along the field lines suppresses any conditions for reconnection. It, therefore, appears that, to first order, the choice of heating prescription defines whether the prominence-internal dynamics are oriented vertically or horizontally. We closely inspected a sample reconnection event and computed the synthetic optically thick radiation using the open-source Lightweaver radiative transfer framework.