📝 SummarXiv

Abstract

Finding low-mass planets around solar-type stars requires to understand the physical variability of the host star, which greatly exceeds the planet-induced radial-velocity modulation. This project aims at analyzing - observationally and theoretically - the character and physical origins of fluctuations in solar photospheric absorption lines. Observationally, photospheric equivalent-width variations were measured in 1000 selected spectra from three years of HARPS-N data of the Sun-as-a-star, showing changes that largely shadow the chromospheric CaII H&K activity-cycle signal, but with much smaller amplitudes on sub-percent levels. Among iron lines, the greatest are for FeII in the blue, while the trends change sign among lines in the green MgI triplet and between Balmer lines. No variation was seen in the semi-forbidden MgI 457.1 nm. Theoretically, hydrodynamic 3D modeling of solar surface convection produced time sequences of synthetic high-resolution spectral atlases. Radial velocities averaged over small simulation areas jitter by some +-150 m/s, scaling to 2 m/s for the full solar disk on timescales of granular convection. Among different lines, jittering is in phase, but amplitudes differ by about one tenth of their values: greater for stronger and for ionized lines, decreasing at longer wavelengths.