Properties of Supersonic Evershed Downflows

TL;DR

This study investigates supersonic Evershed downflows in sunspot penumbrae using high-resolution spectropolarimetric data, revealing their properties, dynamics, and association with magnetic fields and shocks.

Contribution

It provides the first detailed analysis of the physical properties and behavior of supersonic Evershed downflows in sunspot penumbrae.

Findings

Supersonic downflows are found in compact patches in the mid and outer penumbra.

These downflows are associated with strong, vertical, and reversed magnetic fields.

Downflows produce shocks that enhance temperature and create bright grains.

Abstract

We study supersonic Evershed downflows in a sunspot penumbra by means of high spatial resolution spectropolarimetric data acquired in the Fe I 617.3 nm line with the CRISP instrument at the Swedish 1-m Solar Telescope. Physical observables, such as Dopplergrams calculated from line bisectors and Stokes V zero-crossing wavelengths, and Stokes V maps in the far red wing, are used to find regions where supersonic Evershed downflows may exist. We retrieve the LOS velocity and the magnetic field vector in these regions using two-component inversions of the observed Stokes profiles with the help of the SIR code. We follow these regions during their lifetime to study their temporal behavior. Finally, we carry out a statistical analysis of the detected supersonic downflows to characterize their physical properties. Supersonic downflows are contained in compact patches moving outward, which are located in the mid and outer penumbra. They are observed as bright, roundish structures at the outer end of penumbral filaments that resemble penumbral grains. The patches may undergo fragmentations and mergings during their lifetime, even some of them are recurrents. Supersonic downflows are associated with strong and rather vertical magnetic fields with a reversed polarity compared to that of the sunspot. Our results suggest that downflows returning back to the solar surface with supersonic velocities are abruptly stopped in dense deep layers and produce a shock. Consequently, this shock enhances the temperature and is detected as a bright grain in the continuum filtergrams, which could explain the existence of outward moving grains in the mid and outer penumbra.