Abstract
Context. Understanding stellar activity in solar-type stars is crucial
for the physics of stellar atmospheres as well as for ongoing exoplanet
programmes. Aims: We aim to test how well we understand stellar
activity using our own star, the Sun, as a test case. Methods: We
performed a detailed study of the main optical activity indicators (Ca
II H & K, Balmer lines, Na I D1 D2, and He I
D3) measured for the Sun using the data provided by the
HARPS-N solar-telescope feed at the Telescopio Nazionale Galileo. We
made use of periodogram analyses to study solar rotation, and we used
the pool variance technique to study the temporal evolution of active
regions. The correlations between the different activity indicators as
well as the correlations between activity indexes and the derived
parameters from the cross-correlation technique are analysed. We also
study the temporal evolution of these correlations and their possible
relationship with indicators of inhomogeneities in the solar photosphere
like sunspot number or radio flux values. Results: The value of
the solar rotation period is found in all the activity indicators, with
the only exception being Hδ. The derived values vary from 26.29
days (Hγ line) to 31.23 days (He I). From an analysis of sliding
periodograms we find that in most of the activity indicators the
spectral power is split into several "bands" of periods around 26 and 30
days. They might be explained by the migration of active regions between
the equator and a latitude of ˜30°, spot evolution, or a
combination of both effects. A typical lifetime of active regions of
approximately ten rotation periods is inferred from the pooled variance
diagrams, which is in agreement with previous works. We find that
Hα, Hβ, Hγ, Hɛ, and He I show a significant
correlation with the S index. Significant correlations between the
contrast, bisector span, and the heliocentric radial velocity with the
activity indexes are also found. We show that the full width at half
maximum, the bisector, and the disc-integrated magnetic field correlate
with the radial velocity variations. The correlation of the S index and
Hα changes with time, increasing with larger sun spot numbers and
solar irradiance. A similar tendency with the S index and radial
velocity correlation is also present in the data. Conclusions:
Our results are consistent with a scenario in which higher activity
favours the correlation between the S index and the Hα activity
indicators and between the S index and radial velocity variations.
Table A.1 is only available at the CDS via anonymous ftp to http://cdsarc.u-strasbg.fr
(ftp://130.79.128.5) or via http://cdsarc.u-strasbg.fr/viz-bin/qcat?J/A+A/627/A118
Original language | English |
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Journal | Astronomy & Astrophysics |
Volume | 627 |
DOIs | |
Publication status | Published - 01 Jul 2019 |
Keywords
- Sun: activity
- Sun: chromosphere
- Sun: rotation
- techniques: spectroscopic
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Dive into the research topics of 'Temporal evolution and correlations of optical activity indicators measured in Sun-as-a-star observations'. Together they form a unique fingerprint.Student theses
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Understand thy star, understand thy planet
Costes, J. (Author), Watson, C. (Supervisor) & de Mooij, E. (Supervisor), Dec 2021Student thesis: Doctoral Thesis › Doctor of Philosophy
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