Shell mergers in the late stages of massive star evolution: new insight from 3D hydrodynamic simulations

TL;DR

This study uses 3D hydrodynamic simulations to investigate shell mergers in massive stars, revealing complex dynamics, faster mixing, and asymmetric compositions that differ from traditional 1D models, impacting stellar evolution predictions.

Contribution

It provides the first detailed 3D simulation analysis of shell mergers in massive stars, highlighting mechanisms and effects not captured by 1D models.

Findings

Confirmation of shell merging in 3D simulations

Identification of entrainment and erosion as key mechanisms

Observation of asymmetric, dipolar chemical distributions

Abstract

One-dimensional (1D) stellar evolution models are widely used across various astrophysical fields, however they are still dominated by important uncertainties that deeply affect their predictive power. Among those, the merging of independent convective regions is a poorly understood phenomenon predicted by some 1D models but whose occurrence and impact in real stars remain very uncertain. Being an intrinsically multi-D phenomenon, it is challenging to predict the exact behaviour of shell mergers with 1D models. In this work, we conduct a detailed investigation of a multiple shell merging event in a 20 M$_\odot$ star using 3D hydrodynamic simulations. Making use of the active tracers for composition and the nuclear network included in the 3D model, we study the merging not only from a dynamical standpoint but also considering its nucleosynthesis and energy generation. Our simulations confirm the occurrence of the merging also in 3D, but reveal significant differences from the 1D case. Specifically, we identify entrainment and the erosion of stable regions as the main mechanisms that drive the merging, we predict much faster convective velocities compared to the mixing-length-theory velocities, and observe multiple burning phases within the same merged shell, with important effects for the chemical composition of the star, which presents a strongly asymmetric (dipolar) distribution. We expect that these differences will have important effects on the final structure of massive stars and thus their final collapse dynamics and possible supernova explosion, subsequently affecting the resulting nucleosynthesis and remnant.