Classifying metal-poor stars with machine learning using nucleosynthesis calculations
Abstract
We apply the capabilities of machine learning (ML) to discern patterns in order to classify metal-poor stars. To do so, we train an ML model on a bank of nucleosynthesis calculations derived from hydrodynamic simulations for events such as neutron star mergers where the rapid () neutron capture process can take place. Likewise we consider a bank of calculations from simulations of the slow () neutron capture process and also consider a few calculations for the intermediate () neutron capture process. We demonstrate that the ML does well overall in recognizing the process from the process, and after training on theoretical calculations ML stellar assignments match conventional labels 87% of the time. We highlight that this method then points to stars that could benefit from additional observational measurements. We also demonstrate that the ML assigns some of the presently considered -process stars to instead be of or in origin, but likewise, finds stars currently labeled as to be potentially more aligned with enrichment. This first application of ML to classify metal-poor star enrichment using theoretical nucleosynthesis calculations thus reveals the promise, and some challenges, associated with this new data-driven path forward.
Keywords
Cite
@article{arxiv.2505.14563,
title = {Classifying metal-poor stars with machine learning using nucleosynthesis calculations},
author = {Nicole Vassh and Yilin Wang and Richard M. Woloshyn and Michelle P. Kuchera and Maude Lariviere and Kayle Majic and Benoit Cote},
journal= {arXiv preprint arXiv:2505.14563},
year = {2025}
}
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