Multiple and changing cycles of active stars

Oláh, K.; Kollath, Zoltán; Granzer, T.; Strassmeier, K. G.; Lanza, A. F.; Järvinen, S. P.; Korhonen, H.; Baliunas, S. L.; Soon, Willie; Messina, S.; Cutispoto, G.

doi:10.1051/0004-6361/200811304

Cited by 192 publications

(238 citation statements)

References 45 publications

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“…Stellar cycles can be associated with quasi-sinusoidal or highly anharmonic variations of the proxies, they show single or multiple periodicities, and their periods may change versus time (cf. Oláh et al 2009). The relationship of the cycle period to the stellar parameters is by no means a simple one.…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, changing of the cycle period as well as multiperiodic variations are often observed (cf. Oláh et al 2009), which may be related to the complex feedback mechanisms operating in a highly non-linear stellar dynamo (cf. Spiegel 2009).…”

Section: Stellar Cycles From Photospheric Proxiesmentioning

confidence: 99%

“…Since stellar cycles are manifestations of stellar dynamos whose regimes mainly depend on the dynamo number D, most of the studies have focussed on the relationship between the period of the cycle and the rotation period, or the Rossby number, assumed to be a better proxy for D. A plot of the cycle period P cyc vs. the rotation period P rot shows a large scatter, particularly for P rot < 10 − 20 days and a generally weak correlation between P cyc and P rot (cf., e.g., Saar & Brandeburg 1999;Oláh et al 2009). When the cycle period is measured in units of the rotation period of the star and plotted vs. the Rossby number, the correlation improves if the stars are subdivided into three branches (cf.…”

Section: Dependence Of the Cycle Period On Stellar Parametersmentioning

confidence: 99%

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Stellar magnetic cycles

Lanza

2009

Proc. IAU

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Abstract. The solar activity cycle is a manifestation of the hydromagnetic dynamo working inside our star. The detection of activity cycles in solar-like stars and the study of their properties allow us to put the solar dynamo in perspective, investigating how dynamo action depends on stellar parameters and stellar structure. Nevertheless, the lack of spatial resolution and the limited time extension of stellar data pose limitations to our understanding of stellar cycles and the possibility to constrain dynamo models. I briefly review some results obtained from disc-integrated proxies of stellar magnetic fields and discuss the new opportunities opened by space-borne photometry made available by MOST, CoRoT, Kepler, and GAIA, and by new ground-based spectroscopic or spectropolarimetric observations. Stellar cycles have a significant impact on the energetic output and circumstellar magnetic fields of late-type active stars which affects the interaction between stars and their planets. On the other hand, a close-in massive planet could affect the activity of its host star. Recent observations provide circumstantial evidence of such an interaction with possible consequences for stellar activity cycles.

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Section: Discussionmentioning

confidence: 99%

Section: Stellar Cycles From Photospheric Proxiesmentioning

confidence: 99%

Section: Dependence Of the Cycle Period On Stellar Parametersmentioning

confidence: 99%

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Stellar magnetic cycles

Lanza

2009

Proc. IAU

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“…However, significant uncertainties in our current understanding of the solar dynamo mechanism motivates us to confront our theoretical ideas of magnetic field generation with the wider space parameters available from stellar activity observations (Noyes et al 1984a;Baliunas et al 1995;Giampapa 2005;Böhm-Vitense 2007;Oláh et al 2009;Donati and Landstreet 2009;Reiners 2012, and references therein). While, in principle, different stars with different properties may host distinct classes of MHD dynamos, a good starting assumption is that a reasonable model of solar and stellar magnetism should be able to reproduce the range of stellar activity taking into account appropriate changes in the internal driving mechanisms.…”

Section: Solar Dynamics and Magnetism In A Stellar Contextmentioning

confidence: 99%

The Solar-Stellar Connection

Brun¹,

García²,

Houdek³

et al. 2017

Space Sciences Series of ISSI

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We discuss how recent advances in observations, theory and numerical simulations have allowed the stellar community to progress in its understanding of stellar convection, rotation and magnetism and to assess the degree to which the Sun and other stars share similar dynamical properties. Ensemble asteroseismology has become a reality with the advent of large time domain studies, especially from space missions. This new capability has provided improved constraints on stellar rotation and activity, over and above that obtained via traditional techniques such as spectropolarimetry or CaII H&K observations. New data and surveys covering large mass and age ranges have provided a wide parameter space to confront theories of stellar magnetism. These new empirical databases are complemented by theoretical advances and improved multi-D simulations of stellar dynamos. We trace these pathways through which a lucid and more detailed picture of magnetohydrodynamics of solar-like stars is beginning to emerge and discuss future prospects.

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“…They did not discuss a possible change in the level of spottedness itself, though. Oláh et al (2000) favoured a length of 16.2 years on a time base of 18.5 years and quote a significant remaining period of 2.4 years. Adding four more years of data, the preferred cycle length was back to 12.2 years (see Oláh & Strassmeier 2002).…”

Section: Introductionmentioning

confidence: 99%

The chromospherically active binary star EI Eridani: II. Long‐term Doppler imaging

2009

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Data from 11 years of continuous spectroscopic observations of the active RS CVn-type binary star EI Eridani -gained at NSO/McMath-Pierce, KPNO/Coudé Feed and during the MUSICOS 98 campaign -were used to obtain 34 Doppler maps in three spectroscopic lines for 32 epochs, 28 of which are independent of each other. Various parameters are extracted from our Doppler maps: average temperature, fractional spottedness, and longitudinal and latitudinal spot-occurrence functions. We find that none of these parameters show a distinct variation nor a correlation with the proposed activity cycle as seen from photometric long-term observations. This suggests that the photometric brightness cycle may not necessarily be due to just a cool spot cycle. The general morphology of the spot pattern remains persistent over the whole period of 11 years. A large cap-like polar spot was recovered from all our images. A high degree of variable activity was noticed near latitudes of ≈60-70 • where the appendages of the polar spot emerged and dissolved.

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Multiple and changing cycles of active stars

Cited by 192 publications

References 45 publications

Stellar magnetic cycles

Stellar magnetic cycles

The Solar-Stellar Connection

The chromospherically active binary star EI Eridani: II. Long‐term Doppler imaging

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