Temporal evolution of short-lived penumbral microjets

DOI: 
10.1051/0004-6361/202038370
Publication date: 
01/10/2020
Main author: 
Siu-Tapia, A. L.
IAA authors: 
Siu-Tapia, A. L.;Bellot Rubio, L. R.;Orozco Suárez, D.;Gafeira, R.
Authors: 
Siu-Tapia, A. L.;Bellot Rubio, L. R.;Orozco Suárez, D.;Gafeira, R.
Journal: 
Astronomy and Astrophysics
Refereed: 
Yes
Publication type: 
Article
Volume: 
642
Pages: 
A128
Abstract: 
Context. Penumbral microjets (PMJs) is the name given to elongated jet-like brightenings observed in the chromosphere above sunspot penumbrae. They are transient events that last from a few seconds to several minutes, and their origin is presumed to be related to magnetic reconnection processes. Previous studies have mainly focused on their morphological and spectral characteristics, and more recently on their spectropolarimetric signals during the maximum brightness stage. Studies addressing the temporal evolution of PMJs have also been carried out, but they are based on spatial and spectral time variations only. <BR /> Aims: Here we investigate, for the first time, the temporal evolution of the polarization signals produced by short-lived PMJs (lifetimes &lt; 2 min) to infer how the magnetic field vector evolves in the upper photosphere and mid-chromosphere. <BR /> Methods: We use fast-cadence spectropolarimetric observations of the Ca II 854.2 nm line taken with the CRisp Imaging Spectropolarimeter at the Swedish 1 m Solar Telescope. The weak-field approximation (WFA) is used to estimate the strength and inclination of the magnetic field vector. By separating the Ca II 854.2 nm line into two different wavelength domains to account for the chromospheric origin of the line core and the photospheric contribution to the wings, we infer the height variation of the magnetic field vector. <BR /> Results: The WFA reveals larger magnetic field changes in the upper photosphere than in the chromosphere during the PMJ maximum brightness stage. In the photosphere, the magnetic field inclination and strength undergo a transient increase for most PMJs, but in 25% of the cases the field strength decreases during the brightening. In the chromosphere, the magnetic field tends to be slightly stronger during the PMJs. <BR /> Conclusions: The propagation of compressive perturbation fronts followed by a rarefaction phase in the aftershock region may explain the observed behavior of the magnetic field vector. The fact that such behavior varies among the analyzed PMJs could be a consequence of the limited temporal resolution of the observations and the fast-evolving nature of the PMJs.
Database: 
ADS
SCOPUS
URL: 
https://ui.adsabs.harvard.edu/#abs/2020A&A...642A.128S/abstract
ADS Bibcode: 
2020A&A...642A.128S
Keywords: 
sunspots;Sun: chromosphere;Sun: magnetic fields;Astrophysics - Solar and Stellar Astrophysics