The solar photospheric silicon abundance according to CO5BOLD: Investigating line broadening, magnetic fields, and model effects

TL;DR

This study derives the solar silicon abundance using advanced 3D model atmospheres and spectral synthesis, analyzing line broadening, magnetic effects, and model parameters to refine abundance estimates.

Contribution

It provides a new, precise silicon abundance measurement using CO5BOLD models with a carefully selected line sample and improved spectral synthesis techniques.

Findings

Derived silicon abundance: log ε_Si = 7.57 ± 0.04

Identified and corrected line broadening issues

Quantified effects of magnetic fields and model resolution

Abstract

In this work, we present a photospheric solar silicon abundance derived using CO5BOLD model atmospheres and the LINFOR3D spectral synthesis code. Previous works have differed in their choice of a spectral line sample and model atmosphere as well as their treatment of observational material, and the solar silicon abundance has undergone a downward revision in recent years. We additionally show the effects of the chosen line sample, broadening due to velocity fields, collisional broadening, model spatial resolution, and magnetic fields. CO5BOLD model atmospheres for the Sun were used in conjunction with the LINFOR3D spectral synthesis code to generate model spectra, which were then fit to observations in the Hamburg solar atlas. We present a sample of 11 carefully selected lines (from an initial choice of 39 lines) in the optical and infrared, made possible with newly determined oscillator strengths for the majority of these lines. Our final sample includes seven optical Si I lines, three infrared Si I lines, and one optical Si II line. We derived a photospheric solar silicon abundance of $\log \epsilon_\mathrm{Si} = 7.57 \pm 0.04$, including a $-0.01$ dex correction from Non-Local Thermodynamic Equilibrium (NLTE) effects. Combining this with meteoritic abundances and previously determined photospheric abundances results in a metal mass fraction Z/X = $0.0220 \pm 0.0020$. We found a tendency of obtaining overly broad synthetic lines. We mitigated the impact of this by devising a de-broadening procedure. The over-broadening of synthetic lines does not substantially affect the abundance determined in the end. It is primarily the line selection that affects the final fitted abundance.