Are solar brightness variations faculae- or spot-dominated?

TL;DR

This study uses the SATIRE model to analyze how faculae and spots contribute to solar brightness variations across different wavelengths, timescales, and observer positions, revealing complex dependencies and implications for stellar variability interpretation.

Contribution

It provides a detailed assessment of facular and spot contributions to solar brightness variability considering observer inclination and wavelength, enhancing understanding of stellar photometric variability.

Findings

Spot dominance in rotational variability from the ecliptic plane.

Facular contribution increases with observer inclination.

11-year variability shows near-complete faculae-spot compensation.

Abstract

Regular spaceborne measurements have revealed that solar brightness varies on multiple timescales, variations on timescales greater than a day being attributed to surface magnetic field. Independently, ground-based and spaceborne measurements suggest that Sun-like stars show a similar, but significantly broader pattern of photometric variability. 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 as well as its facular and spot contributions depend on the wavelength, timescale of variability, and position of the observer relative to the ecliptic plane. We perform calculations with the SATIRE model, which returns solar brightness with daily cadence from solar disc area coverages of various magnetic features. Moving the observer away from the ecliptic plane increases the amplitude of 11-year variability as it would be seen in Str\"omgren $(b+y)/2$ 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 Str\"omgren $(b+y)/2$ 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. The rotational solar brightness variability as it would appear in Kepler and CoRoT passband 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 $i=45^{\circ}$.