Analysis of the linear approximation of seismic inversions for various structural pairs

TL;DR

This paper investigates the limitations of linear structural inversion techniques in asteroseismology, analyzing the validity of the linear assumption across various structural variables and conditions using numerical experiments.

Contribution

It introduces a new (A, Y) structural kernel pair and evaluates the validity of linear assumptions for different stellar variables and model uncertainties.

Findings

The linear approximation's validity varies with structural variables and stellar model uncertainties.

Metallicity, equation of state, and microphysics inaccuracies significantly affect inversion results.

The new (A, Y) kernel pair extends the theoretical framework for stellar structural inversions.

Abstract

Thanks to space-based photometry missions CoRoT and Kepler, we benefit from a wealth of seismic data for stars other than the sun. In the future, K2, Tess, and Plato will complement this data and provide observations in addition to those already at hand. The availability of this data leads to questions on how it is feasible to extend linear structural inversion techniques to stars other than the sun. Linked to this problem is the question of the validity of the linear assumption. In this study, we analyse its limitations with respect to changes of structural variables.We wish to provide a more extended theoretical background to structural linear inversions by doing a study of the validity of the linear assumption for various structural variables. First, we recall the origins of the linear assumption for structural stellar inversions and explain its importance for asteroseismic studies. We recall the impact of unknown structural quantities such as the mass and the radius of the star on structural inversion results. We explain how kernels for new structural variables can be derived using two methods, one suited to asteroseismic targets, the other to helioseismic targets. For this second method, we present a new structural pair, namely the (A, Y) structural kernels. The kernels are tested in various numerical experiments that enable us to evaluate the weaknesses of different pairs and the domains of validity of their respective linear regime. The numerical tests we carry out allow us to disentangle the impact of various uncertainties in stellar models on the verification of the linear integral relations. We show the importance of metallicity, the equation of state, extra-mixing, and inaccuracies in the microphysics. We discuss the limitations of the method of conjugated functions due to the lack of extremely precise determinations of masses or radii in the asteroseismology.