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Main Authors: Margueron, Jérôme, Drischler, Christian, Dutra, Mariana, Gandolfi, Stefano, Gezerlis, Alexandros, Grams, Guilherme, Guillot, Sébastien, Kumar, Rohit, Lalit, Sudhanva, Lourenço, Odilon, Somasundaram, Rahul, Tews, Ingo, Vidaña, Isaac
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.20434
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author Margueron, Jérôme
Drischler, Christian
Dutra, Mariana
Gandolfi, Stefano
Gezerlis, Alexandros
Grams, Guilherme
Guillot, Sébastien
Kumar, Rohit
Lalit, Sudhanva
Lourenço, Odilon
Somasundaram, Rahul
Tews, Ingo
Vidaña, Isaac
author_facet Margueron, Jérôme
Drischler, Christian
Dutra, Mariana
Gandolfi, Stefano
Gezerlis, Alexandros
Grams, Guilherme
Guillot, Sébastien
Kumar, Rohit
Lalit, Sudhanva
Lourenço, Odilon
Somasundaram, Rahul
Tews, Ingo
Vidaña, Isaac
contents Systematic comparisons across theoretical predictions for the properties of dense matter, nuclear physics data, and astrophysical observations (also called meta-analyses) are performed. Existing predictions for symmetric nuclear and neutron matter properties are considered, and they are shown in this paper as an illustration of the present knowledge. Asymmetric matter is constructed assuming the isospin asymmetry quadratic approximation. It is employed to predict the pressure at twice saturation energy-density based only on nuclear-physics constraints, and we find it compatible with the one from the gravitational-wave community. To make our meta-analysis transparent, updated in the future, and to publicly share our results, the Python toolkit \texttt{nucleardatapy} is described and released here. Hence, this paper accompanies \texttt{nucleardatapy}, which simplifies access to nuclear-physics data, including theoretical calculations, experimental measurements, and astrophysical observations. This Python toolkit is designed to easily provide data for: i) predictions for uniform matter (from microscopic or phenomenological approaches); ii) correlation among nuclear properties induced by experimental and theoretical constraints; iii) measurements for finite nuclei (nuclear chart, charge radii, neutron skins or nuclear incompressibilities, etc.) and hypernuclei (single particle energies); and iv) astrophysical observations. This toolkit provides data in a unified format for easy comparison and provides new meta-analysis tools. It will be continuously developed, and we expect contributions from the community in our endeavor.
format Preprint
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institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The nucleardatapy toolkit for simple access to experimental nuclear data, astrophysical observations, and theoretical predictions
Margueron, Jérôme
Drischler, Christian
Dutra, Mariana
Gandolfi, Stefano
Gezerlis, Alexandros
Grams, Guilherme
Guillot, Sébastien
Kumar, Rohit
Lalit, Sudhanva
Lourenço, Odilon
Somasundaram, Rahul
Tews, Ingo
Vidaña, Isaac
Nuclear Theory
Systematic comparisons across theoretical predictions for the properties of dense matter, nuclear physics data, and astrophysical observations (also called meta-analyses) are performed. Existing predictions for symmetric nuclear and neutron matter properties are considered, and they are shown in this paper as an illustration of the present knowledge. Asymmetric matter is constructed assuming the isospin asymmetry quadratic approximation. It is employed to predict the pressure at twice saturation energy-density based only on nuclear-physics constraints, and we find it compatible with the one from the gravitational-wave community. To make our meta-analysis transparent, updated in the future, and to publicly share our results, the Python toolkit \texttt{nucleardatapy} is described and released here. Hence, this paper accompanies \texttt{nucleardatapy}, which simplifies access to nuclear-physics data, including theoretical calculations, experimental measurements, and astrophysical observations. This Python toolkit is designed to easily provide data for: i) predictions for uniform matter (from microscopic or phenomenological approaches); ii) correlation among nuclear properties induced by experimental and theoretical constraints; iii) measurements for finite nuclei (nuclear chart, charge radii, neutron skins or nuclear incompressibilities, etc.) and hypernuclei (single particle energies); and iv) astrophysical observations. This toolkit provides data in a unified format for easy comparison and provides new meta-analysis tools. It will be continuously developed, and we expect contributions from the community in our endeavor.
title The nucleardatapy toolkit for simple access to experimental nuclear data, astrophysical observations, and theoretical predictions
topic Nuclear Theory
url https://arxiv.org/abs/2506.20434