A change in the relationship between chromospheric activity and the large-scale magnetic field for G stars on the main sequence
Creators
- 1. University of Southern Queensland
- 2. Max Planck Institute for Solar System Research, Göttingen, Germany
- 3. Université de Montpellier, CNRS
- 4. University of Vienna
- 5. Université de Toulouse, CNRS
- 6. University of St Andrews
- 7. European Space Agency; University of Exeter
- 8. Trinity College Dublin; Leiden University
- 9. University of Göttingen; CERN, Switzerland
Contributors
Description
The internal magnetic fields of cool stars are known to power activity in stellar chromospheres, but there is still much to discover about the relationship between the large-scale magnetic field and chromospheric activity. We have revisited this relationship by surveying the chromospheric activity (logR'HK) and surface-averaged longitudinal magnetic field strength (Bl) for 954 mid-F to mid-M dwarf stars using observations from 3 the PolarBase spectropolarimetric database. We computed the mean logR'HK, mean Bl and their variability amplitudes from time-series observations, and found that for F, K and M stars, the mean logR'HK declines fairly smoothly with the mean logBl and also the amplitude of logR'HK variability. Meanwhile, for G stars on the main sequence, chromospheric activity appears to drop from logR'HK ~ -4.4 to -4.8, with minimal change in the logBl and the amplitude of logR'HK variability. At a similar logR'HK level, we also see a switch from mixed magnetic field geometries to dominantly poloidal magnetic field geometries, as shown by published large-scale magnetic field maps derived using Zeeman Doppler Imaging. These results support a change in the magnetic surface properties of G stars that occurs on the main sequence.
Files
CoolStars21_poster.pdf
Files
(900.9 kB)
Name | Size | Download all |
---|---|---|
md5:dd768417577b5a1553225f5aad551f94
|
900.9 kB | Preview Download |
Additional details
Related works
- Is derived from
- 10.1093/mnras/stac1291 (DOI)
References
- Vaughan et al. (1978), PASP, 90, 267
- Noyes et al. (1984), ApJ, 279, 763
- Marsden et al. (2014), MNRAS, 444, 3517
- Suarez Mascareno et al. (2015), MNRAS, 452, 2745
- Donati et al. (1997), MNRAS, 291, 658