2026-03-04 バーミンガム大学
The Sun during two periods: recent solar minimum in 2019, and solar maximum that preceded it (photo by NASA/SDO/Joy Ng)
<関連情報>
- https://www.birmingham.ac.uk/news/2026/forty-years-of-data-give-unique-insight-into-suns-inner-life
- https://academic.oup.com/mnras/article/547/1/stag277/8472642?login=false
バーミンガム太陽振動ネットワーク(BiSON)によって観測された4つの連続した太陽活動周期極小期の地震の多様性 The seismic diversity of four successive solar cycle minima as observed by the Birmingham Solar-Oscillations Network (BiSON)
Sarbani Basu,William J Chaplin,Rachel Howe,Yvonne Elsworth,Steven J Hale,Eleanor Murray
Monthly Notices of the Royal Astronomical Society Published:04 March 2026
DOI:https://doi.org/10.1093/mnras/stag277
ABSTRACT
We have used data collected by the Birmingham Solar-Oscillations Network (BiSON) to perform a helioseismic diagnosis of changes to the Sun’s internal structure between four successive solar cycle minima, beginning with the minimum at the end of cycle 21 and ending with the recent minimum at the beginning of cycle 25. The unique duration of the BiSON data base makes such a study possible. We used the low-degree BiSON p-mode frequencies to constrain structural changes between minima in the layers above ≈0.9R⦿. We accomplished this by examining variations in the He ii ionization zone signature; and by inverting the frequency differences to infer changes in the sound speed. Additionally, we employed frequency differences between various solar models that had subtle modifications to their internal structures to facilitate analysis of the observations. We find evidence for small, but marginally significant, changes in structure between different minima. The He ii signature was larger, and the sound speed in the range ≈0.93 to 0.97R⦿ was slightly higher, during the cycle 23/24 minimum, than during the other minima. The cycle 23/24 minimum was the deepest, as measured by proxies of global solar activity. These findings are consistent with magnetic flux levels having been lower in this minimum than the others, resulting in a higher gas pressure, higher temperatures, and higher sound speed. Our results demonstrate the potential of using asteroseismic data to perform similar analyses on other solar-type stars.
