Structure of prominence legs: Plasma and magnetic field

TL;DR

This study combines multi-wavelength high-resolution observations and spectropolarimetry to analyze the plasma and magnetic field structure of a solar prominence tornado, revealing complex plasma flows and predominantly horizontal magnetic fields.

Contribution

It provides new insights into the magnetic and plasma dynamics of prominence legs, challenging the rotating tornado model with detailed observational evidence.

Findings

Prominence legs are strongly absorbing in AIA and look rotating or oscillating.

Magnetic fields in the prominence legs are predominantly horizontal.

Observed plasma flows include counterstreaming and loop structures.

Abstract

We investigate the properties of a `solar tornado' observed on 15 July 2014, and aim to link the behaviour of the plasma to the internal magnetic field structure of the associated prominence. We made multi-wavelength observations with high spatial resolution and high cadence using SDO/AIA, the IRIS spectrograph and the Hinode/SOT instrument. Along with spectropolarimetry provided by the THEMIS telescope we have coverage of both optically thick emission lines and magnetic field information. AIA reveals that the two legs of the prominence are strongly absorbing structures which look like they are rotating, or oscillating in the plane of the sky. The two prominence legs, which are both very bright in Ca II (SOT), are not visible in the IRIS Mg II slit-jaw images. This is explained by the large optical thickness of the structures in Mg II which leads to reversed profiles, and hence to lower integrated intensities at these locations than in the surroundings. Using lines formed at temperatures lower than 1 MK, we measure relatively low Doppler shifts on the order of +/- 10 km/s in the tornado-like structure. Between the two legs we see loops in Mg II, with material flowing from one leg to the other, as well as counterstreaming. It is difficult to interpret our data as showing two rotating, vertical structures which are unrelated to the loops. This kind of `tornado' scenario does not fit with our observations. The magnetic field in the two legs of the prominence is found to be preferentially horizontal.