Alive and well: a short review about standard solar models

TL;DR

This review discusses recent developments in standard solar models, including spectroscopic challenges, neutrino measurements, and opacity experiments, highlighting their implications and current limitations.

Contribution

It provides a comprehensive overview of recent experimental and observational advances affecting the accuracy and understanding of standard solar models.

Findings

Borexino measured solar neutrino fluxes with high precision.

Opacity experiments at solar-like conditions have been conducted.

Spectroscopic techniques challenge existing solar model accuracy.

Abstract

Standard solar models (SSMs) provide a reference framework across a number of research fields: solar and stellar models, solar neutrinos, particle physics the most conspicuous among them. The accuracy of the physical description of the global properties of the Sun that SSMs provide has been challenged in the last decade by a number of developments in stellar spectroscopic techniques. Over the same period of time, solar neutrino experiments, and Borexino in particular, have measured the four solar neutrino fluxes from the pp-chains that are associated with 99\% of the nuclear energy generated in the Sun. Borexino has also set the most stringent limit on CNO energy generation, only $\sim 40\%$ larger than predicted by SSMs. More recently, and for the first time, radiative opacity experiments have been performed at conditions that closely resemble those at the base of the solar convective envelope. In this article, we review these developments and discuss the current status of SSMs, including its intrinsic limitations.