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Main Authors: Manchon, L., Deal, M., Marques, J. P. C., Lebreton, Y.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.02801
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author Manchon, L.
Deal, M.
Marques, J. P. C.
Lebreton, Y.
author_facet Manchon, L.
Deal, M.
Marques, J. P. C.
Lebreton, Y.
contents We present Cesam2k20, the latest version of the hydrostatic stellar evolution code CESAM originally developed by P. Morel and collaborators. Over the last three decades, it has undergone many improvements and has been extensively tested against other stellar evolution codes before being selected to compute the first-generation grid of stellar models for the PLATO mission. Among all the developments made thus far, Cesam2k20 now implements state-of-the-art models for the transport of chemical elements and angular momentum. It was recently made publicly available with an ecosystem of other codes interfaced with it: 1D and 2D oscillation codes ADIPLS and ACOR, optimisation program OSM, and Python utility package pycesam. This paper recalls the numerical peculiarities of Cesam2k20, namely, the use of a collocation method where the structure variables are decomposed as piecewise polynomials projected on a B-spline basis. Here, we review the options available for modelling the different physical processes. In particular, we illustrate the improvements made in the transport of chemical elements and angular momentum with a series of standard and non-standard solar models.
format Preprint
id arxiv_https___arxiv_org_abs_2511_02801
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Cesam2k20: A code for a new generation of stellar evolution models. I. Description of the code
Manchon, L.
Deal, M.
Marques, J. P. C.
Lebreton, Y.
Solar and Stellar Astrophysics
We present Cesam2k20, the latest version of the hydrostatic stellar evolution code CESAM originally developed by P. Morel and collaborators. Over the last three decades, it has undergone many improvements and has been extensively tested against other stellar evolution codes before being selected to compute the first-generation grid of stellar models for the PLATO mission. Among all the developments made thus far, Cesam2k20 now implements state-of-the-art models for the transport of chemical elements and angular momentum. It was recently made publicly available with an ecosystem of other codes interfaced with it: 1D and 2D oscillation codes ADIPLS and ACOR, optimisation program OSM, and Python utility package pycesam. This paper recalls the numerical peculiarities of Cesam2k20, namely, the use of a collocation method where the structure variables are decomposed as piecewise polynomials projected on a B-spline basis. Here, we review the options available for modelling the different physical processes. In particular, we illustrate the improvements made in the transport of chemical elements and angular momentum with a series of standard and non-standard solar models.
title Cesam2k20: A code for a new generation of stellar evolution models. I. Description of the code
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2511.02801