A Stringent Limit on the Mass Production Rate of r-process Elements in the Milky Way

We analyze data from several studies of metal-poor stars in the Milky Way, focusing individually on the main r-process elements (Eu) as well as the lighter neutron-capture element Sr, at the neutron-magic peak N = 50. Because these elements were injected in an explosion, we calculate the mass swept...

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Bibliographic Details
Published in:The Astrophysical journal 2018-06, Vol.860 (2), p.89
Main Authors: Macias, Phillip, Ramirez-Ruiz, Enrico
Format: Article
Language:English
Subjects:
Astronomical models
Astrophysics
Chemical evolution
Constraint modelling
Dilution
Ejecta
Explosions
Galactic evolution
Galaxy: abundances
Iron
Mass production
Metallicity
Milky Way
Nuclear capture
nuclear reactions, nucleosynthesis, abundances
Organic chemistry
Stars
stars: abundances
stars: neutron
Strontium
Supernovae
Synthesis
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Summary:We analyze data from several studies of metal-poor stars in the Milky Way, focusing individually on the main r-process elements (Eu) as well as the lighter neutron-capture element Sr, at the neutron-magic peak N = 50. Because these elements were injected in an explosion, we calculate the mass swept up when the blast wave first becomes radiative, yielding a lower limit for the dilution of such elements and hence a lower limit on the ejecta mass that is incorporated into the next generation of stars. Our study demonstrates that in order to explain the largest enhancements in [Eu/Fe] observed in stars at low [Fe/H] metallicities, individual r-process production events must synthesize a minimum of roughly 10−3 M of r-process material. This provides a critical constraint on galactic chemical evolution models. We also show independently that if the site of Mg production is the same as that of Eu, individual injection events must synthesize up to ∼10−3 M of r-process material. On the other hand, demanding that Sr traces Mg production results in r-process masses per event of ∼10−5 M . This suggests that the astrophysical sites responsible for the genesis of the main r-process elements need to operate at a drastically reduced rate when compared to standard core-collapse supernovae.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/aac3e0