# Statistical properties of coronal hole rotation rates: Are they linked   to the solar interior?

**Authors:** Salome R. Bagashvili, Bidzina M. Shergelashvili, Darejan R. Japaridze,, Bidzina B. Chargeishvili, Alexander G. Kosovichev, Vasil Kukhianidze, George, Ramishvili, Teimuraz V. Zaqarashvili, Stefaan Poedts, Maxim L. Khodachenko,, Patrick De Causmaecker

arXiv: 1706.04464 · 2017-07-26

## TL;DR

This study analyzes coronal hole rotation rates to explore their potential connection to the Sun's internal rotation, revealing that CHs may be linked to the tachocline region and the solar magnetic field.

## Contribution

It provides the first statistical analysis of CH rotation rates over a solar cycle segment and compares them with internal solar rotation profiles, suggesting a link to the tachocline.

## Key findings

- CH rotation rates do not match photospheric profiles
- CH angular velocities exceed photospheric velocities at high latitudes
- CH rotation profile coincides with the tachocline region

## Abstract

The present paper discusses results of a statistical study of the characteristics of coronal hole (CH) rotation in order to find connections to the internal rotation of the Sun. The goal is to measure CH rotation rates and study their distribution over latitude and their area sizes. In addition, the CH rotation rates are compared with the solar photospheric and inner layer rotational profiles. We study coronal holes observed within $\pm 60$ latitude and longitude degrees from the solar disc centre during the time span from the 1 January 2013 to 20 April 2015, which includes the extended peak of solar cycle 24.We used data created by the Spatial Possibilistic Clustering Algorithm (SPoCA), which provides the exact location and characterisation of solar coronal holes using SDO=AIA 193 {\AA} channel images. The CH rotation rates are measured with four-hour cadence data to track variable positions of the CH geometric centre. North-south asymmetry was found in the distribution of coronal holes: about 60 percent were observed in the northern hemisphere and 40 percent were observed in the southern hemisphere. The smallest and largest CHs were present only at high latitudes. The average sidereal rotation rate for 540 examined CHs is $13:86 (\pm 0:05)$ degrees/d. Conclusions. The latitudinal characteristics of CH rotation do not match any known photospheric rotation profile. The CH angular velocities exceed the photospheric angular velocities at latitudes higher than 35-40 degrees. According to our results, the CH rotation profile perfectly coincides with tachocline and the lower layers of convection zone at around 0.71 $R_{\odot}$; this indicates that CHs may be linked to the solar global magnetic field, which originates in the tachocline region.

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1706.04464/full.md

## References

46 references — full list in the complete paper: https://tomesphere.com/paper/1706.04464/full.md

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Source: https://tomesphere.com/paper/1706.04464