Standard solar models: a perspective from updated solar neutrino fluxes and the gravity-mode period spacing

TL;DR

This paper combines neutrino flux measurements and helioseismic data, including gravity modes, to evaluate and constrain solar models, revealing discrepancies and potential avenues for refining our understanding of the Sun's internal structure.

Contribution

It integrates neutrino and helioseismic diagnostics to assess solar models, highlighting the limitations of current models in reproducing gravity-mode period spacing and constraining solar interior properties.

Findings

CNO neutrino flux favors high-metallicity models

Mild nuclear screening adjustments can align low-metallicity models with neutrino data

Standard models cannot reproduce gravity-mode period spacing within observed uncertainties

Abstract

Context: The Sun is by far a privileged target for testing stellar models with unique precision. A recent concern appeared with the progress in the solar surface abundances derivation that has led to a decrease of the solar metallicity. While the ancient high-metallicity models were in fair agreement with other solar observational indicators, it is no longer the case for low-metallicity models. Recent collection of data are however promising to shed a new light on it. For instance, the Borexino collaboration released in 2020 the first-ever complete estimate of neutrinos emitted in the CNO cycle. It has reaffirmed the role of the neutrino constraints in the solar modelling process and its associated issues. In parallel, newly claimed detection of solar gravity modes of oscillations offers another opportunity of probing the stratification in the Sun's central layers. Aims: We propose to combine the diagnoses from neutrinos and helioseismology, both from pressure and gravity modes, for assessing the predictions of solar models. We compare in detail the different physical prescriptions currently at disposal for stellar model computations. Results: The CNO neutrino flux confirms a preference for high-metallicity models. Nevertheless, we found that mild modification of the nuclear screening factors can re-match low-metallicity model predictions to observed fluxes, although it does not restore the agreement with the helioseismic frequency ratios. Neither the high-metallicity or low-metallicity models are able to reproduce the gravity-mode period spacing. The disagreement is huge, more than 100$\sigma$ to the reported value. Reversely, the family of standard models narrows the expected range of the Sun's period spacing: between $\sim$2150 to $\sim$2190~s. Moreover, we show this indicator can constrain the chemical mixture, opacity, and to a lower extent nuclear reactions in solar models.