Authors: Khagendra Katuwal (New Mexico State University), Dr. R.T. James McAteer (New Mexico State University)

A study of the unbalanced magnetic polarity distribution of 70 coronal holes was performed. Data from the Helioseismic and Magnetic Imager were used to examine the photospheric line-of-sight magnetic field (BLOS) beneath these coronal holes. The skewness (S) values of the BLOS distributions revealed significant asymmetry, characterized by the dominance of one magnetic polarity, with ∼88% of the coronal holes exhibiting a skewness value ranging from ±(0.20 to 0.40). The corresponding magnetic flux imbalance (Φimb) ranges from 20% to 45%. In contrast, quiet-Sun regions show symmetric magnetic field distributions with skewness values less than 0.11 and flux imbalance less than 11.0%. A study of a coronal hole as it traverses across the disk shows that the magnetic field distribution does not evolve significantly over this time, remaining stable across half a solar rotation. A moderate correlation (r = 0.60) between the magnetic flux imbalance and the speed of associated HSSs (vHSS) suggests that flux imbalance may contribute to the generation of these faster solar wind streams. These results imply that regions with higher flux imbalance (Φimb), indicative of more open magnetic field structures, present more favorable conditions for plasma acceleration as compared to closed bipolar field, but the moderate correlation indicates that other factors may also play important roles.