Rotational Characteristics of the Solar Transition Region Using SDO/AIA 304 Å Images

Wu, Qian-Rui; Zheng, Sheng; Zeng, Shu-Guang; Wan, Miao; Zeng, Xiang-Yun; Deng, Lin-Hua; Huang, Yao

doi:10.3847/1538-4357/ace623

ApJ

2023

DOI: 10.3847/1538-4357/ace623

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Rotational Characteristics of the Solar Transition Region Using SDO/AIA 304 Å Images

Qian-Rui Wu,

Sheng Zheng,

Shu-Guang Zeng

et al.

Abstract: To date, the rotational characteristics of the solar transition region remain unclear. In this work, by applying the flux modulation method to the images derived from the Solar Dynamics Observatory/Atmospheric Imaging Assembly between 2011 and 2022 at 304 Å wavelength, we have studied the rotation of the solar transition region, and the results obtained are as follows. The solar transition region rotates differentially, while, from the perspective of the entire time interval, the rotation coefficients A and B … Show more

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Cited by 5 publications

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Evolution of solar wind sources and coronal rotation driven by the cyclic variation of the Sun’s large-scale magnetic field

Finley,

Brun

2023

A&A

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Context. The strength and morphology of the Sun’s magnetic field evolve significantly during the solar cycle, with the overall polarity of the Sun’s magnetic field reversing during the maximum of solar activity. Long-term changes are also observed in sunspot and geomagnetic records; however, systematic magnetic field observations are limited to the last four cycles. Aims. Here, we investigate the long-term evolution of the Sun’s magnetic field, and the influence this has on the topology and rotation of the solar corona. Methods. The Sun’s photospheric magnetic field was decomposed into spherical harmonics using synoptic Carrington magnetograms from (1) the Wilcox Solar Observatory, (2) the Michelson Doppler Imager on board the Solar and Heliospheric Observatory, and (3) the Helioseismic and Magnetic Imager on board the Solar Dynamics Observatory. The time evolution of the spherical harmonic coefficients was used to explore the variation of the Sun’s magnetic field, with a focus on the large-scale modes. Potential field source surface extrapolations of the photospheric field were computed to follow topological changes in the corona. Results. The sources of the Sun’s open magnetic field vary between the polar coronal holes and activity-driven features such as active regions, and equatorial coronal holes. Consequently, the mean rotation rate of the solar wind is modulated during each cycle by the latitudinal variation of open field footpoints, with slower rotation during minima and faster (Carrington-like) rotation during maxima. Conclusions. Coronal rotation is sensitive to cycle to cycle differences in the polar field strengths and hemispherical flux emergence rates. The mean rotation of the corona varies similarly to the ratio of quadrupole to dipole energy. Cycle 23 maintained a larger fraction of quadrupolar energy in the declining phase, which kept the sources of the open magnetic flux closer to the equator, extending the period of faster equator-ward connectivity. The ratio of quadrupole to dipole energy could be a useful proxy when examining the impact of differential rotation on the coronae of other Sun-like stars.

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Evolution of solar wind sources and coronal rotation driven by the cyclic variation of the Sun’s large-scale magnetic field

Finley,

Brun

2023

A&A

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Rotation signal on the full disc of the solar chromosphere

Wan,

Deng,

Zeng

et al. 2024

Monthly Notices of the Royal Astronomical Society

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The rotation signal on the full disc of the solar chromosphere was studied by using the Ca ii K normalized intensity from 938 Carrington rotation (CR) synoptic maps (from CR827 to CR1764) obtained from the Mount Wilson Observatory during the period of 1915 August 10 to 1985 July 7. In this study, our main focus is on the distribution characteristics of the rotation signal on the full disc of the solar chromosphere and its variation with the solar cycle. We found that the chromospheric rotation signal is more pronounced in the latitudinal belt of sunspot activity and tends to extend to higher latitudes, and the trend is essentially the same for each solar cycle. The chromospheric rotation signal is also found to have phase differences in latitudes. The period of the chromospheric rotation signal varies regularly in latitudes, but its phase variation is irregular. In addition, we found that the intensity background is lowest in the latitudinal belt of sunspot drift where the chromospheric rotation signal is generated, but it increases with latitude and tends to extend to higher latitudes. We discussed the possible mechanisms of the above analysis results and thought that the chromospheric rotation signal is mainly caused by sunspots and plages.

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Solar Rotation and Activity for Cycle 24 from SDO/AIA Observations

Shokri,

Alipour,

Safari

2024

ApJ

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Differential rotation plays a crucial role in the dynamics of the Sun. We study the solar rotation and its correlation with solar activity by applying a modified machine learning algorithm to identify and track coronal bright points (CBPs) from the Solar Dynamics Observatory/Atmospheric Imaging Assembly observations at 193 Å during cycle 24. For more than 321,440 CBPs, the sidereal and meridional velocities are computed. We find the occurring height of CBPs to be about 5627 km above the photosphere. We obtain a rotational map for the corona by tracking CBPs at the formation height of Fe xii (193 Å) emissions. The equatorial rotation (14.°40 to 14.°54 day−1) and latitudinal gradient of rotation (−3.°0 to −2.°64 day−1) show very slightly positive and negative trends with solar activity (sunspots and flares), respectively. For cycle 24, our investigations show that the northern hemisphere has more differential rotation than the southern hemisphere, confirmed by the asymmetry of the midlatitude rotation parameter. The asymmetry (ranked) of the latitudinal gradient of the rotation parameter is concordant with the sunspot numbers for 7 yr within the 9 yr of the cycle; however, for only 3 yr, it is concordant with the flare index. The minimum horizontal Reynolds stress changes from about −2500 m2 s−2 (corresponding to high activity) in 2012 and 2014 to −100 m2 s−2 (corresponding to low activity) in 2019 over 5° to 35° latitudes within cycle 24. We conclude that the negative horizontal Reynolds stress (momentum transfer toward the Sun’s equator) is a helpful indication of solar activity.

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Rotational Characteristics of the Solar Transition Region Using SDO/AIA 304 Å Images

Cited by 5 publications

References 51 publications

Evolution of solar wind sources and coronal rotation driven by the cyclic variation of the Sun’s large-scale magnetic field

Evolution of solar wind sources and coronal rotation driven by the cyclic variation of the Sun’s large-scale magnetic field

Rotation signal on the full disc of the solar chromosphere

Solar Rotation and Activity for Cycle 24 from SDO/AIA Observations

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