The role of the Fraunhofer lines in solar brightness variability

Шапиро, А. И.; Solanki, S. K.; Krivova, N. A.; Tagirov, Rinat; Schmutz, W.

doi:10.1051/0004-6361/201526483

Cited by 33 publications

(42 citation statements)

References 100 publications

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“…One can expect that the facular contrast in Sun-like stars depends on the stellar brightness temperature (cf. Beeck et al 2015) and on the stellar metallicity (since the facular contrast is strongly affected by the weak atomic and molecular lines, see Shapiro et al 2015). A small change of the facular contrast might break a delicate balance between facular and spot contributions to Strömgren b and y photometry and significantly increase the stellar brightness variability.…”

Section: Discussionmentioning

confidence: 99%

“…Figure 3 demonstrates that the spectral dependences of the spot and facular components are remarkably different. The facular component has a very complex profile due to the strong influence of Fraunhofer lines (Unruh et al 1999(Unruh et al , 2008Shapiro et al 2015). The effect of Fraunhofer lines on the spot component is much more subtle and exposes itself as barely visible spikes superposed on otherwise undulating dependence (see discussion in Unruh et al 2008;Shapiro et al 2015).…”

Section: Activity Cycle Timescalementioning

confidence: 99%

“…(4)). As a result, the transition from the faculae-to the spot-dominated regime of rotational variability happens already around 400 nm, immediately longward of the CN violet system (which amplifies the facular contrast and thus ensures the faculae-dominated regime of variability, see discussion in Shapiro et al 2015).…”

Section: Timescale Of Solar Rotationmentioning

confidence: 99%

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Are solar brightness variations faculae- or spot-dominated?

Шапиро

Solanki

Krivova

et al. 2016

A&A

Self Cite

101

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Context. Regular spaceborne measurements have revealed that solar brightness varies on multiple timescales, variations on timescales greater than a day being attributed to a surface magnetic field. Independently, ground-based and spaceborne measurements suggest that Sun-like stars show a similar, but significantly broader pattern of photometric variability. Aims. To understand whether the broader pattern of stellar variations is consistent with the solar paradigm, we assess relative contributions of faculae and spots to solar magnetically-driven brightness variability. We investigate how the solar brightness variability and its facular and spot contributions depend on the wavelength, timescale of variability, and position of the observer relative to the ecliptic plane. Methods. We performed calculations with the SATIRE model, which returns solar brightness with daily cadence from solar disc area coverages of various magnetic features. We took coverages as seen by an Earth-based observer from full-disc SoHO/MDI and SDO/HMI data and projected them to mimic out-of-ecliptic viewing by an appropriate transformation. Results. Moving the observer away from the ecliptic plane increases the amplitude of 11-year variability as it would be seen in Strömgren (b + y)/2 photometry, but decreases the amplitude of the rotational brightness variations as it would appear in Kepler and CoRoT passbands. The spot and facular contributions to the 11-year solar variability in the Strömgren (b + y)/2 photometry almost fully compensate each other so that the Sun appears anomalously quiet with respect to its stellar cohort. Such a compensation does not occur on the rotational timescale. Conclusions. The rotational solar brightness variability as it would appear in the Kepler and CoRoT passbands from the ecliptic plane is spot-dominated, but the relative contribution of faculae increases for out-of-ecliptic viewing so that the apparent brightness variations are faculae-dominated for inclinations less than about i = 45• . Over the course of the 11-year activity cycle, the solar brightness variability is faculae-dominated shortwards of 1.2 μm independently of the inclination.

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Section: Discussionmentioning

confidence: 99%

Section: Activity Cycle Timescalementioning

confidence: 99%

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Are solar brightness variations faculae- or spot-dominated?

Шапиро

Solanki

Krivova

et al. 2016

A&A

Self Cite

101

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“…9). (Shapiro et al 2015). Together with the inclination of the rotation axis, metallicity is also known to have an effect on the visibility of activity-related phenomena like spots and faculae (Shapiro et al 2014).…”

Section: Discussionmentioning

confidence: 99%

The Influence of Metallicity on Stellar Differential Rotation and Magnetic Activity

Karoff

Metcalfe

Santos

et al. 2018

ApJ

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Observations of Sun-like stars over the last half-century have improved our understanding of how magnetic dynamos, like that responsible for the 11-year solar cycle, change with rotation, mass and age. Here we show for the first time how metallicity can affect a stellar dynamo. Using the most complete set of observations of a stellar cycle ever obtained for a Sun-like star, we show how the solar analog HD 173701 exhibits solar-like differential rotation and a 7.4-year activity cycle. While the duration of the cycle is comparable to that generated by the solar dynamo, the amplitude of the brightness variability is substantially stronger. The only significant difference between HD 173701 and the Sun is its metallicity, which is twice the solar value. Therefore, this provides a unique opportunity to study the effect of the higher metallicity on the dynamo acting in this star and to obtain a comprehensive understanding of the physical mechanisms responsible for the observed photometric variability. The observations can be explained by the higher metallicity of the star, which is predicted to foster a deeper outer convection zone and a higher facular contrast, resulting in stronger variability.

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“…Furthermore, the fact that SATIRE-S reproduces the correct level of the variation in the Mn line provides strong support to the overall spectral profile of the irradiance variability computed with SATIRE-S. On the one hand, Yeo et al (2015) have recently demonstrated that the magnitude of the changes in the UV returned by SATIRE-S agrees well with the most stable satellite measurements. On the other hand, since spectral lines determine the amplitude and even the A33, page 7 of 8 phase of the visible irradiance variations (Shapiro et al 2015), our finding here indicates that the magnitude of the variability in the visible is also adequate. Finally, the model also reproduces the changes in the TSI that are dominated by changes in the UV and the visible and are measured far more reliably than changes in the spectral irradiance (Yeo et al 2014a).…”

Section: Discussionmentioning

confidence: 52%

Variation of the Mn I 539.4 nm line with the solar cycle

Danilović

Solanki

Livingston

et al. 2016

A&A

Self Cite

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Context. As a part of the long-term program at Kitt Peak National Observatory (KPNO), the Mn i 539.4 nm line has been observed for nearly three solar cycles using the McMath telescope and the 13.5 m spectrograph in double-pass mode. These full-disk spectrophotometric observations revealed an unusually strong change of this line's parameters over the solar cycle. Aims. Optical pumping by the Mg II k line was originally proposed to explain these variations. More recent studies have proposed that this is not required and that the magnetic variability (i.e., the changes in solar atmospheric structure due to faculae) might explain these changes. Magnetic variability is also the mechanism that drives the changes in total solar irradiance variations (TSI). With this work we investigate this proposition quantitatively by using the same model that was earlier successfully employed to reconstruct the irradiance. Methods. We reconstructed the changes in the line parameters using the model SATIRE-S, which takes only variations of the daily surface distribution of the magnetic field into account. We applied exactly the same model atmospheres and value of the free param- It also provides independent confirmation of solar irradiance models which are based on the assumption that irradiance variations are caused by the evolution of the solar surface magnetic flux. The result obtained here also supports the spectral irradiance variations computed by these models.

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The role of the Fraunhofer lines in solar brightness variability

Cited by 33 publications

References 100 publications

Are solar brightness variations faculae- or spot-dominated?

Are solar brightness variations faculae- or spot-dominated?

The Influence of Metallicity on Stellar Differential Rotation and Magnetic Activity

Variation of the Mn I 539.4 nm line with the solar cycle

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