The magnetic topology of the inverse Evershed flow

TL;DR

This study investigates the magnetic structure and driving forces of the inverse Evershed flow in sunspots, revealing it is driven by a gas pressure difference along magnetic field lines consistent with the siphon flow model.

Contribution

The paper combines high-resolution observations and magnetic field extrapolation to identify the magnetic topology and pressure-driven flow mechanism of the inverse Evershed flow.

Findings

Magnetic field lines reach about 3 Mm in height and 13 Mm in length.

Flow velocities of 2-10 km/s are explained by pressure differences.

The inverse Evershed flow is driven by a gas pressure difference consistent with the siphon flow scenario.

Abstract

The inverse Evershed flow (IEF) is a mass motion towards sunspots at chromospheric heights. We combined high-resolution observations of NOAA 12418 from the Dunn Solar Telescope and vector magnetic field measurements from the Helioseismic and Magnetic Imager (HMI) to determine the driver of the IEF. We derived chromospheric line-of-sight (LOS) velocities from spectra of H$\alpha$ and Ca II IR. The HMI data were used in a non-force-free magnetic field extrapolation to track closed field lines near the sunspot in the active region. We determined their length and height, located their inner and outer foot points, and derived flow velocities along them. The magnetic field lines related to the IEF reach on average a height of 3 Mm over a length of 13 Mm. The inner (outer) foot points are located at 1.2 (1.9) sunspot radii. The average field strength difference $\Delta B$ between inner and outer foot points is +400 G. The temperature difference $\Delta T$ is anti-correlated with $\Delta B$ with an average value of -100 K. The pressure difference $\Delta p$ is dominated by $\Delta B$ and is primarily positive with a driving force towards the inner foot points of 1.7 kPa on average. The velocities predicted from $\Delta p$ reproduce the LOS velocities of 2-10 km s$^{-1}$ with a square-root dependence. We find that the IEF is driven along magnetic field lines connecting network elements with the outer penumbra by a gas pressure difference that results from a difference in field strength as predicted by the classical siphon flow scenario.