Stellar activity cycles as revealed by long-term beat-like patterns from light curves of Kepler

The present review will focus upon the incidence, form, and characteristic timescale of long-term chromospheric variations that, from the work of O.C. Wilson and his successors, can be descerned in records of CaII H and K emission now extending over 16 years, and the relation, if any, between properties of activity cycles and stellar mass, age, and rate of rotation, in the light of current evidence.

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HD 38858: a solar-type star with an activity cycle of ∼10.8 yr

Astronomy and Astrophysics ◽

10.1051/0004-6361/201833330 ◽

2018 ◽

Vol 620 ◽

pp. A34 ◽

Cited By ~ 3

Author(s):

M. Flores ◽

J. F. González ◽

M. Jaque Arancibia ◽

C. Saffe ◽

A. Buccino ◽

...

Keyword(s):

Radial Velocity ◽

Activity Cycle ◽

Earth Planet ◽

Stellar Activity ◽

Balmer Lines ◽

Solar Type ◽

Activity Cycles ◽

Novel Strategy ◽

Solar Type Star

Context. The detection of chromospheric activity cycles in solar-analogue and twin stars can be used to place the solar cycle in a wider context. However, relatively few of these stars with activity cycles have been detected. It is well known that the cores of the Ca II H&K lines are modulated by stellar activity. The behaviour of the Balmer and other optical lines with stellar activity is not yet completely understood. Aims. We search for variations in the Ca II H&K, Balmer, and Fe II lines modulated by stellar activity. In particular, we apply a novel strategy to detect possible shape variations in the Hα line. Methods. We analysed activity signatures in HD 38858 using HARPS and CASLEO spectra obtained between 2003 and 2017. We calculated the Mount Wilson index (SMW), log(R′HK), and the statistical moments of the Ca II H&K, Balmer, and other optical lines. We searched for periodicities using the generalized Lomb-Scargle periodogram. Results. We detect a long-term activity cycle of 10.8 yr in Ca II H&K and Hα in the solar-analogue star HD 38858. In contrast, this cycle is marginally detected in the Fe II lines. We also detect a noticeable variation in radial velocity that seems to be produced by stellar activity. Conclusions. HD 38858 is the second solar-analogue star where we find a clear activity cycle that is replicated in the Balmer lines. Spectral indexes based on the shape of Hα line seem to be more reliable than the fluxes in the same line for detecting activity variations. The cyclic modulation we detected gives place to a variation in radial velocity that previously has been associated with a super-Earth planet. Finally, due to the similarity of HD 38858 with the Sun, we recommend to continue monitoring this star.

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Stellar Activity and Calcium Emission Variability

International Astronomical Union Colloquium ◽

10.1017/s0252921100096093 ◽

1983 ◽

Vol 71 ◽

pp. 195-199

Author(s):

Sallie L. Baliunas

Keyword(s):

Solar Activity ◽

Magnetic Fields ◽

Magnetic Activity ◽

Small Scale ◽

Physical Parameters ◽

Stellar Activity ◽

Ongoing Work ◽

Chromospheric Emission ◽

Activity Cycles

ABSTRACT.Time series analysis of fluctuations of Ca II H and K chromospheric emission has provided us with much information concerning stellar activity. On all timescales, events which parallel solar behavior can be observed: activity cycles, on timescales of years; rotation of stars and evolution of active areas on timescales of days to weeks; flare-like phenomena on timescales as short as minutes.We expect that the analogues of solar activity exist on other stars . By studying stellar counterparts to solar activity, we can hope to investigate the physical parameters which are thought to influence chromospheric and coronal activity. The stellar surfaces are usually spatially unresolvable; it is thus difficult to measure directly either small-scale surface inhomogeneities or the associated magnetic fields expected from spatially restricted areas.On the Sun, however, areas with strong surface magnetic fields show intense chromospheric Ca II H and K emission (Babcock and Babcock 1955; Skumanich et al 1975). Although indirect, the Ca II H and K features are good indicators of stellar magnetic activity. A major advantage of the Ca II features is their accessibility to ground-based observatories. Long-term synoptic programs are in progress to monitor stellar chromospheric activity, and this paper will highlight ongoing work at Mt. Wilson. Monitoring variations of Ca II H and K chromospheric emission over different timescales can reveal different physical phenomena: (1) Long-term (years) variations corresponding to stellar activity cycles; (2) intermediate term (days-months) variations indicating rotation or evolution of stellar active areas; (3) short-term (minutes-hours) variations resulting from impulsive and flare-like phenomena.

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Properties of stellar activity cycles

Proceedings of the International Astronomical Union ◽

10.1017/s1743921316003276 ◽

2015 ◽

Vol 11 (A29A) ◽

pp. 354-359 ◽

Cited By ~ 1

Author(s):

Heidi Korhonen

Keyword(s):

High Precision ◽

Stellar Activity ◽

Active Stars ◽

Activity Cycles

AbstractThe current photometric datasets, that span decades, allow for studying long-term cycles on active stars. Complementary Ca H&K observations give information also on the cycles of normal solar-like stars, which have significantly smaller, and less easily detectable, spots. In the recent years, high precision space-based observations, for example from the Kepler satellite, have allowed also to study the sunspot-like spot sizes in other stars. Here I review what is known about the properties of the cyclic stellar activity in other stars than our Sun.

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Joint Discussion 8 Solar and stellar activity cycles

Proceedings of the International Astronomical Union ◽

10.1017/s174392130701054x ◽

2006 ◽

Vol 2 (14) ◽

pp. 271-272

Author(s):

Alexander G. Kosovichev ◽

Klaus G. Strassmeier

Keyword(s):

Magnetic Field ◽

Time Scales ◽

Tree Ring ◽

Solar Magnetic Field ◽

Sunspot Cycle ◽

Magnetic Cycle ◽

Stellar Activity ◽

Tree Ring Data ◽

Activity Cycles

The solar magnetic field and its associated atmospheric activity exhibits periodic variations on a number of time scales. The 11-year sunspot cycle and its underlying 22-year magnetic cycle are, besides the 5-minute oscillation, the most widely known. Amplitudes and periods range from a few parts per million (ppm) and 2–3 minutes for p-modes in sunspots, a few 10 ppm and 10 minutes for the granulation turn around, a few 100 ppm and weeks for the lifetime of plages and faculae, 1000 ppm and 27 days for the rotational signal from spots, to the long-term cycles of 90 yr (Gleissberg cycle), 200 - 300 yr (Wolf, Spörer, Maunder minima), 2,400 yr from 14C tree-ring data, and possibly in excess of 100,000 yr.

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Theoretical Models of Stellar Activity Cycles

Proceedings of the International Astronomical Union ◽

10.1017/s1743921314004785 ◽

2012 ◽

Vol 10 (H16) ◽

pp. 113-114

Author(s):

Emre Işık

Keyword(s):

Surface Flux ◽

Theoretical Models ◽

Dynamo Action ◽

Cyclic Activity ◽

Flux Transport ◽

Stellar Activity ◽

Active Stars ◽

Activity Cycles ◽

Stellar Properties

AbstractWe discuss possible mechanisms underlying the observed features of stellar activity cycles, such as multiple periodicities in very active stars, non-cyclic activity observed in moderately active stars, and spatial distribution of stellar magnetic regions. We review selected attempts to model the dependence of stellar activity cycles on stellar properties, and their comparison with observations. We suggest that combined effects of dynamo action, flux emergence and surface flux transport have substantial effects on the long-term manifestations of stellar magnetism.

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CCD Observations and Analysis of the W UMA Type Binary SS Arietis

Highlights of Astronomy ◽

10.1017/s1539299600021328 ◽

1998 ◽

Vol 11 (1) ◽

pp. 382-382

Author(s):

Wonyong Han ◽

Chun-Hwey Kim ◽

Jae Woo Lee ◽

Ho-Il Kim ◽

Woo-Baik Lee

Keyword(s):

Period Change ◽

Light Curves ◽

Period Variation ◽

Light Elements ◽

Astronomy Observatory ◽

Third Body ◽

Convective Envelope ◽

Ccd Observations ◽

The Times

The BVR CCD observations of W UMa-type eclipsing binary SS Arietis were made for ten nights from November 1996 to December 1996 at the Sobaeksan Astronomy Observatory. From the observed light curves, nine new times of minimum lights were derived from the Kwee and van Woerden’s method. Improved light elements for this system were determined from these minimum lights with all the published minima. The analysis of the times of minima of SS Ari confirms that the orbital period of SS Ari has been suffering from a sinusoidal variation as the suggestions of other previous investigators (Kaluzny & Pojmanski 1984, Demircan & Selam 1993). The calculation shows that the cyclic period change has a period of about 56.3yrs with an amplitude of about 0.d052. The period variation has been discussed in terms of two potential mechanisms: 1) the light-time effect due to a hypothetical third body and 2) deformations in the convective envelope of a magnetically active component. The BVR light curves of SS Ari observed for about one month showed the existence of cycle to cycle light variations. Long-term light changes of SS Ari are discussed in terms of the period variation of the binary system.

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Long-term Photometric Monitoring of FUor and FUor-like Objects

Communications of the Byurakan Astrophysical Observatory ◽

10.52526/25792776-2018.2.2-240 ◽

2018 ◽

pp. 240-248

Author(s):

E. Semkov ◽

S. Ibryamov ◽

S. Peneva ◽

A. Mutafov

Keyword(s):

Light Curve ◽

Significant Role ◽

Stellar Evolution ◽

Photographic Plate ◽

Light Curves ◽

Curve Shape ◽

Rate Of Increase ◽

Fu Ori ◽

Photometric Monitoring

A phenomenon with a significant role in stellar evolution is the FU Orionis (FUor) type of outburst. The first three (classical) FUors (FU Ori, V1515 Cyg and V1057 Cyg) are well-studied and their light curves are published in the literature. But recently, over a dozen new objects of this type were discovered, whose photometric history we do not know well. Using recent data from photometric monitoring and data from the photographic plate archives we aim to study, the long-term photometric behavior of FUor and FUor-like objects. The construction of the historical light curves of FUors could be very important for determining the beginning of the outburst, the time to reach the maximum light, the rate of increase and decrease in brightness, the pre-outburst variability of the star. So far we have published our results for the light curves of V2493 Cyg, V582 Aur, Parsamian 21 and V1647 Ori. In this paper we present new data that describe more accurate the photometric behavior of these objects. In comparing our results with light curves of the well-studied FUors (FU Ori, V1515 Cyg and V1057 Cyg), we conclude that every object shows different photometric behavior. Each known FUor has a different rate of increase and decrease in brightness and a different light curve shape.

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Solar and stellar activity cycles

Journal of Physics Conference Series ◽

10.1088/1742-6596/118/1/012032 ◽

2008 ◽

Vol 118 ◽

pp. 012032 ◽

Cited By ~ 11

Author(s):

Matthias Rempel

Keyword(s):

Stellar Activity ◽

Activity Cycles

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