Projects per year
Abstract
Information on the rotation rate of the corona, and its variation over latitude and solar cycle, is valuable for making global connections between the corona and the Sun, for global estimates of reconnection rates and as a basic parameter for solar-wind modeling. Here, we use a time series of tomographical maps gained from coronagraph observations between 2007 and 2020 to directly measure the longitudinal drift of high-density streamers over time. The method reveals abrupt changes in rotation rates, revealing a complex relationship between the coronal rotation and the underlying photosphere. The majority of rates are between -1.°0 to +0.°5 day-1 relative to the standard Carrington rate of 14.°18 day-1, although rates are measured as low as -2.°2 day-1 and as high as 1.°6 day-1. Equatorial rotation rates during the 2008 solar minimum are slightly faster than the Carrington rate, with an abrupt switch to slow rotation in 2009, then a return to faster rates in 2017. Abrupt changes and large variations in rates are seen at all latitudes. Comparison with a magnetic model suggests that periods of equatorial fast rotation are associated with times when a large proportion of the magnetic footpoints of equatorial streamers are near the equator, and we interpret the abrupt changes in terms of the latitudinal distribution of the streamer photospheric footpoints. The coronal rotation rate is a key parameter for solar-wind models, and variations of up to a degree per day or more can lead to large systematic errors over forecasting periods of longer than a few days. The approach described in this paper gives corrected values that can form a part of future forecasting efforts.
Original language | English |
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Article number | 42 |
Number of pages | 14 |
Journal | Astrophysical Journal |
Volume | 928 |
Issue number | 1 |
DOIs | |
Publication status | Published - 25 Mar 2022 |
Keywords
- 360
- The Sun and the Heliosphere
Fingerprint
Dive into the research topics of 'A Solar-cycle Study of Coronal Rotation: Large Variations, Rapid Changes, and Implications for Solar-wind Models'. Together they form a unique fingerprint.Projects
- 3 Finished
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SWEEP: Space Weather Empirical Ensemble Package
Morgan, H. (PI)
Science and Technology Facilities Council
01 Oct 2020 → 30 Sept 2023
Project: Externally funded research
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EMPSOL: An empirical model of the solar wind: a new approach to space weather forecasting
Morgan, H. (PI)
01 Jul 2020 → 30 Jun 2023
Project: Externally funded research
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Solar System Physics at Aberystwyth University
Morgan, H. (PI), Cook, T. (CoI), Gorman, M. (CoI), Li, X. (CoI), Pinter, B. (CoI) & Taroyan, Y. (CoI)
Science and Technology Facilities Council
01 Apr 2019 → 31 Dec 2022
Project: Externally funded research