Polar Field Reversal Observations with Hinode

TL;DR

This study uses Hinode observations to analyze the evolution and reversal of the Sun's polar magnetic fields, highlighting the role of large magnetic patches and their polarity in the reversal process during the solar cycle.

Contribution

It provides detailed measurements of magnetic flux patches in polar regions and links their evolution to the polar field reversal, a novel observational insight.

Findings

Large magnetic patches dominate polar polarity.

Net flux decreases due to fewer large patches and opposite polarity patches.

Small patches and horizontal fields show no significant change.

Abstract

We have been monitoring yearly variation in the Sun's polar magnetic fields with the Solar Optical Telescope aboard {\it Hinode} to record their evolution and expected reversal near the solar maximum. All magnetic patches in the magnetic flux maps are automatically identified to obtain the number density and magnetic flux density as a function of th total magnetic flux per patch. The detected magnetic flux per patch ranges over four orders of magnitude ($10^{15}$ -- $10^{20}$ Mx). The higher end of the magnetic flux in the polar regions is about one order of magnitude larger than that of the quiet Sun, and nearly that of pores. Almost all large patches ($ \geq 10^{18}$ Mx) have the same polarity, while smaller patches have a fair balance of both polarities. The polarity of the polar region as a whole is consequently determined only by the large magnetic concentrations. A clear decrease in the net flux of the polar region is detected in the slow rising phase of the current solar cycle. The decrease is more rapid in the north polar region than in the south. The decrease in the net flux is caused by a decrease in the number and size of the large flux concentrations as well as the appearance of patches with opposite polarity at lower latitudes. In contrast, we do not see temporal change in the magnetic flux associated with the smaller patches ($ < 10^{18}$ Mx) and that of the horizontal magnetic fields during the years 2008--2012.