Systematic and Statistical Uncertainties in Simulated <i>r</i>-Process Abundances due to Uncertain Nuclear Masses

Surman, Rebecca; Mumpower, Matthew; McLaughlin, Gail

doi:10.7566/jpscp.14.010612

Cited by 3 publications

(3 citation statements)

References 13 publications

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“…At subsaturation baryon densities, 0.1n 0 < n < 0.8n 0 , conditions expected in the bottom layers of the inner crust of neutron star, there is a strong competition between the Coulomb and strong interactions, which leads to the emergence of various complex structures with similar energies that are collectively referred to [18,19] are displayed as dots. We have plotted possible r-process trajectories predicted to be realized in the case of two neutron star mergers [16,17] (red circles), in a classical hot (n, γ) ↔ (γ, n) in equilibrium r-process [170] (green circles) with the FRDM model [66] and neutron star merger with the UNEDF1 functional [74] (blue circles). With pink and green bands we display the r-process paths obtained by Mendoza-Temis et al [171] under various conditions using the FRDM model [66] and the Duflo-Zuker model [172].…”

Section: G Neutron Star Crustmentioning

confidence: 99%

“…The 2375 nuclear masses from [18,19] are displayed as dots. We have plotted possible r-process trajectories predicted to be realized in the case of two neutron star mergers [16,17] (red circles), in a classical hot (n, γ) ↔ (γ, n) in equilibrium r-process [170] (green circles) with the FRDM model [66] and neutron star merger with the UNEDF1 functional [74] (blue circles). With pink and green bands we display the r-process paths obtained by Mendoza-Temis et al [171] under various conditions using the FRDM model [66] and the Duflo-Zuker model [172].…”

Section: G Neutron Star Crustmentioning

confidence: 99%

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Minimal nuclear energy density functional

et al. 2018

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We present a minimal nuclear energy density functional (NEDF) called "SeaLL1" that has the smallest number of possible phenomenological parameters to date. SeaLL1 is defined by 7 significant phenomenological parameters, each related to a specific nuclear property. It describes the nuclear masses of even-even nuclei with a mean energy error of 0.97 MeV and a standard deviation 1.46 MeV, two-neutron and two-proton separation energies with rms errors of 0.69 MeV and 0.59 MeV respectively, and the charge radii of 345 even-even nuclei with a mean error r = 0.022 fm and a standard deviation σ r = 0.025 fm. SeaLL1 incorporates constraints on the equation of state (EoS) of pure neutron matter from quantum Monte Carlo calculations with chiral effective field theory two-body (NN) interactions at next-to-next-to-next-to leading order (N2LO) level and three-body (NNN) interactions at the next-to-next-to leading order (N2LO) level. Two of the seven parameters are related to the saturation density and the energy per particle of the homogeneous symmetric nuclear matter, one is related to the nuclear surface tension, two are related to the symmetry energy and its density dependence, one is related to the strength of the spin-orbit interaction, and one is the coupling constant of the pairing interaction. We identify additional phenomenological parameters that have little effect on ground-state properties, but can be used to fine-tune features such as the Thomas-Reiche-Kuhn sum rule, the excitation energy of the giant dipole and Gamow-Teller resonances, the static dipole electric polarizability, and the neutron skin thickness.

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Section: G Neutron Star Crustmentioning

confidence: 99%

Section: G Neutron Star Crustmentioning

confidence: 99%

Minimal nuclear energy density functional

et al. 2018

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“…New Experimental Facilities: Currently, theoretical calculations of r-process nucleosynthesis rely on extensive models of nuclear masses and reactions. The nuclear data uncertainties significantly limit many predictions of astrophysical r-process calculations (e.g., Eichler et al, 2015;Mendoza-Temis et al, 2015;Mumpower et al, 2016;Surman et al, 2017;Barnes et al, 2021). However, upcoming experimental facilities like the Facility for Rare Isotope Beams (FRIB), the Radioactive Isotope Beam Factor (RIBF), the International Facility for Antiproton and Ion Research (FAIR), the Advanced Rare IsotopE Laboratory (ARIEL), and the N = 126 Factory at Argonne will fundamentally transform this landscape (Horowitz et al, 2019).…”

Section: New Instrumentation and Observational And Experimental Facil...mentioning

confidence: 99%

Observations of R-Process Stars in the Milky Way and Dwarf Galaxies

Frebel

2022

Handbook of Nuclear Physics

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This chapter presents an overview of the recent progress on spectroscopic observations of metal-poor stars with r-process element signatures found in the Milky Way's stellar halo and satellite dwarf galaxies. Major empirical lessons related to the origins of the r-process are discussed, including the universality of the observed r-process pattern and deviations from universality among the light r-process elements and actinides. Different astrophysical sites of the r-process based on theoretical expectations are presented, including common and rare supernovae and neutron star mergers. A major distinguishing factor between r-process sites is their delay time distribution. The best constraints on the detailed r-process pattern come from Galactic halo r-process stars, but these cannot provide information on the environment of the stars' birth gas clouds. Studying r-process enrichment within dwarf galaxies can remedy the situation despite the fact that high-resolution spectroscopic observations of individual stars in these systems are very difficult to obtain. A general overview of dwarf galaxy properties and chemical evolution expectations depending on their mass and star formation duration is provided. The r-process trends depend on the stellar mass and star formation durations of dwarf galaxies in a way that clearly shows that the r-process is rare, prolific, and has both prompt and delayed sources. This work complements ongoing theoretical heavy-element nucleosynthesis explorations and experimental measurements of the properties of r-process nuclei, such as with the Facility for Rare Isotope Beams.

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Observations of R-Process Stars in the Milky Way and Dwarf Galaxies

Frebel,

2023

Handbook of Nuclear Physics

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Systematic and Statistical Uncertainties in Simulated r-Process Abundances due to Uncertain Nuclear Masses

Cited by 3 publications

References 13 publications

Minimal nuclear energy density functional

Minimal nuclear energy density functional

Observations of R-Process Stars in the Milky Way and Dwarf Galaxies

Observations of R-Process Stars in the Milky Way and Dwarf Galaxies

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