Observations and Numerical Models of Solar Coronal Heating Associated with Spicules

• Published in: Astrophysical journal. Letters Vol. 845; no. 2; p. L18
• Main Authors: Pontieu, B. De, Moortel, I. De, Martinez-Sykora, J., McIntosh, S. W.
• Format: Journal Article
• Language: English
• Published: Austin The American Astronomical Society 20.08.2017; IOP Publishing; Institute of Physics Publishing Ltd
• Subjects: ASTROPHYSICS, COSMOLOGY AND ASTRONOMY; Atmospheric models; CHROMOSPHERE; Computer simulation; Corona; Coronal heating; Coronal temperatures; DISTURBANCES; ENERGY BALANCE; HEATING; INTERFACES; MAGNETIC FIELDS; MAGNETOHYDRODYNAMICS; MASS; Mathematical models; Numerical models; PLASMA; RESOLUTION; SIMULATION; Solar activity; Solar corona; Solar observatories; SOLAR PROMINENCES; Spicules; Substructures; SUN; Sun: chromosphere; Sun: corona; Sun: magnetic fields; Sun: transition region
• ISSN: 2041-8205; 2041-8213
• DOI: 10.3847/2041-8213/aa7fb4

Spicules have been proposed as significant contributors to the mass and energy balance of the corona. While previous observations have provided a glimpse of short-lived transient brightenings in the corona that are associated with spicules, these observations have been contested and are the subject of a vigorous debate both on the modeling and the observational side. Therefore, it remains unclear whether plasma is heated to coronal temperatures in association with spicules. We use high-resolution observations of the chromosphere and transition region (TR) with the Interface Region Imaging Spectrograph and of the corona with the Atmospheric Imaging Assembly on board the Solar Dynamics Observatory to show evidence of the formation of coronal structures associated with spicular mass ejections and heating of plasma to TR and coronal temperatures. Our observations suggest that a significant fraction of the highly dynamic loop fan environment associated with plage regions may be the result of the formation of such new coronal strands, a process that previously had been interpreted as the propagation of transient propagating coronal disturbances. Our observations are supported by 2.5D radiative MHD simulations that show heating to coronal temperatures in association with spicules. Our results suggest that heating and strong flows play an important role in maintaining the substructure of loop fans, in addition to the waves that permeate this low coronal environment.