Quiet Sun magnetic fields observed by Hinode: Support for a local dynamo

TL;DR

This study uses Hinode observations to analyze quiet Sun magnetic fields over several years, finding no significant variation in magnetic flux or polarization signals, supporting the existence of a local dynamo generating these fields independently of the solar cycle.

Contribution

It provides observational evidence that the quiet Sun magnetic fields are maintained by a local dynamo, with no detectable variation over the solar cycle 23.

Findings

No overall variation in polarization signals from 2006 to 2012.

Magnetic flux follows a power-law distribution with stable index.

Supports the hypothesis of a local dynamo generating quiet Sun magnetic fields.

Abstract

The Hinode mission has revealed copious amounts of horizontal flux covering the quiet Sun. Local dynamo action has been proposed to explain the presence of this flux. We sought to test whether the quiet Sun flux detected by Hinode is due to a local or the global dynamo by studying long-term variations in the polarisation signals detectable at the disc centre of the quiet Sun between November 2006 and May 2012, with particular emphasis on weak signals in the internetwork. The investigation focusses on line-integrated circular polarisation V_tot and linear polarisation LP_tot profiles obtained from the Fe I 6302.5 \AA absorption line in Hinode SOT/SP. Both circular and linear polarisation signals show no overall variation in the fraction of selected pixels from 2006 until 2012. There is also no variation in the magnetic flux in this interval of time. The probability density functions (PDF) of the line-of-sight magnetic flux can be fitted with a power law from 1.17 x 10^17 Mx to 8.53 x 10^18 Mx with index \alpha=-1.82 \pm 0.02 in 2007. The variation of \alpha 's across all years does not exceed a significance of 1\sigma. Linearly polarised features are also fitted with a power law, with index \alpha=-2.60 \pm 0.06 in 2007. Indices derived from linear polarisation PDFs of other years also show no significant variation. Our results show that the ubiquitous horizontal polarisation on the edges of bright granules seen by Hinode are invariant during the minimum of cycle 23. This supports the notion that the weak circular and linear polarisation is primarily caused by an independent local dynamo.