Low Density In-Medium Effects on Light Clusters from Heavy-Ion Data

The modification of the ground state properties of light atomic nuclei in the nuclear and stellar medium is addressed, using chemical equilibrium constants evaluated from a new analysis of the intermediate energy heavy-ion (Xe + Sn) collision data measured by the INDRA Collaboration. Three different...

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Bibliographic Details
Published in:Physical review letters 2020-07, Vol.125 (1), p.1-012701, Article 012701
Main Authors: Pais, Helena, Bougault, Rémi, Gulminelli, Francesca, Providência, Constança, Bonnet, Eric, Borderie, Bernard, Chbihi, Abdelouahad, Frankland, John D., Galichet, Emmanuelle, Gruyer, Diégo, Henri, Maxime, Le Neindre, Nicolas, Lopez, Olivier, Manduci, Loredana, Parlôg, Marian, Verde, Giuseppe
Format: Article
Language:English
Subjects:
Astrophysics
Atomic collisions
Chemical equilibrium
Clusters
Density
Heavy ions
Ideal gas
Ionic collisions
Nuclear Theory
Nuclei (nuclear physics)
Parameterization
Physics
Sigma-mesons
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Summary:The modification of the ground state properties of light atomic nuclei in the nuclear and stellar medium is addressed, using chemical equilibrium constants evaluated from a new analysis of the intermediate energy heavy-ion (Xe + Sn) collision data measured by the INDRA Collaboration. Three different reactions are considered, mainly differing by the isotopic content of the emission source. The thermodynamic conditions of the data samples are extracted from the measured multiplicities allowing for a parametrization of the in-medium modification, determined with the single hypothesis that the different nuclear species in a given sample correspond to a unique common value for the density of the expanding source. We show that this correction, which was not considered in previous analyses of chemical constants from heavy-ion collisions, is necessary, since the observables of the analyzed systems show strong deviations from the expected results for an ideal gas of free clusters. This dataset is further compared to a relativistic mean-field model, and seen to be reasonably compatible with a universal correction of the attractive σ-meson coupling.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.125.012701