Your search keyword '"G. C. McLaughlin"' showing total 7 results

1. Actinide-rich and Actinide-poor r-process-enhanced Metal-poor Stars Do Not Require Separate r-process Progenitors.

Author

Erika M. Holmbeck, Anna Frebel, G. C. McLaughlin, Matthew R. Mumpower, Trevor M. Sprouse, and Rebecca Surman

Subjects

HEAVY elements, NUCLEOSYNTHESIS, STARS, ASSET management accounts

Abstract

The astrophysical production site of the heaviest elements in the universe remains a mystery. Incorporating heavy-element signatures of metal-poor, r-process-enhanced stars into theoretical studies of r-process production can offer crucial constraints on the origin of heavy elements. In this study, we introduce and apply the “actinide-dilution with matching” model to a variety of stellar groups, ranging from actinide-deficient to actinide-enhanced, to empirically characterize r-process ejecta mass as a function of electron fraction. We find that actinide-boost stars do not indicate the need for a unique and separate r-process progenitor. Rather, small variations of neutron richness within the same type of r-process event can account for all observed levels of actinide enhancements. The very low-Ye, fission-cycling ejecta of an r-process event need only constitute 10%–30% of the total ejecta mass to accommodate most actinide abundances of metal-poor stars. We find that our empirical Ye distributions of ejecta are similar to those inferred from studies of GW170817 mass ejecta ratios, which is consistent with neutron-star mergers being a source of the heavy elements in metal-poor, r-process-enhanced stars. [ABSTRACT FROM AUTHOR]

Published

2019

2. r-process nucleosynthesis: connecting rare-isotope beam facilities with the cosmos.

Author

C J Horowitz, A Arcones, B Côté, I Dillmann, W Nazarewicz, I U Roederer, H Schatz, A Aprahamian, D Atanasov, A Bauswein, T C Beers, J Bliss, M Brodeur, J A Clark, A Frebel, F Foucart, C J Hansen, O Just, A Kankainen, and G C McLaughlin

Subjects

NUCLEAR astrophysics, NUCLEOSYNTHESIS, STELLAR mergers, ELECTROMAGNETIC waves, NUCLEAR structure, ASTROPHYSICS

Abstract

This is an exciting time for the study of r-process nucleosynthesis. Recently, a neutron star merger GW170817 was observed in extraordinary detail with gravitational waves and electromagnetic radiation from radio to γ rays. The very red color of the associated kilonova suggests that neutron star mergers are an important r-process site. Astrophysical simulations of neutron star mergers and core collapse supernovae are making rapid progress. Detection of both electron neutrinos and antineutrinos from the next galactic supernova will constrain the composition of neutrino-driven winds and provide unique nucleosynthesis information. Finally, FRIB and other rare-isotope beam facilities will soon have dramatic new capabilities to synthesize many neutron-rich nuclei that are involved in the r-process. The new capabilities can significantly improve our understanding of the r-process and likely resolve one of the main outstanding problems in classical nuclear astrophysics. However, to make best use of the new experimental capabilities and to fully interpret the results, a great deal of infrastructure is needed in many related areas of astronomy, astrophysics, and nuclear theory. We place these experiments in context by discussing astrophysical simulations and observations of r-process sites, observations of stellar abundances, galactic chemical evolution, and nuclear theory for the structure and reactions of very neutron-rich nuclei. This review paper was initiated at a three-week International Collaborations in Nuclear Theory program in June 2016, where we explored promising r-process experiments and discussed their likely impact, and their astronomical, astrophysical, and nuclear theory context. [ABSTRACT FROM AUTHOR]

Published

2019

3. Californium-254 and Kilonova Light Curves.

Author

Y. Zhu, R. T. Wollaeger, N. Vassh, R. Surman, T. M. Sprouse, M. R. Mumpower, P. Möller, G. C. McLaughlin, O. Korobkin, T. Kawano, P. J. Jaffke, E. M. Holmbeck, C. L. Fryer, W. P. Even, A. J. Couture, and J. Barnes

Published

2018

4. Reverse engineering nuclear properties from rare earth abundances in the r process.

Author

M R Mumpower, G C McLaughlin, R Surman, and A W Steiner

Subjects

REVERSE engineering, COSMIC abundances, NEUTRON capture, NUCLEOSYNTHESIS, NUCLEAR physics

Abstract

The bulk of the rare earth elements are believed to be synthesized in the rapid neutron capture process or r process of nucleosynthesis. The solar r-process residuals show a small peak in the rare earths around , which is proposed to be formed dynamically during the end phase of the r process by a pileup of material. This abundance feature is of particular importance as it is sensitive to both the nuclear physics inputs and the astrophysical conditions of the main r process. We explore the formation of the rare earth peak from the perspective of an inverse problem, using Monte Carlo studies of nuclear masses to investigate the unknown nuclear properties required to best match rare earth abundance sector of the solar isotopic residuals. When nuclear masses are changed, we recalculate the relevant β-decay properties and neutron capture rates in the rare earth region. The feedback provided by this observational constraint allows for the reverse engineering of nuclear properties far from stability where no experimental information exists. We investigate a range of astrophysical conditions with this method and show how these lead to different predictions in the nuclear properties influential to the formation of the rare earth peak. We conclude that targeted experimental campaigns in this region will help to resolve the type of conditions responsible for the production of the rare earth nuclei, and will provide new insights into the longstanding problem of the astrophysical site(s) of the r process. [ABSTRACT FROM AUTHOR]

Published

2017

5. Neutron capture on 130Sn during r-process freeze-out.

Author

J Beun, J C Blackmon, W R Hix, G C McLaughlin, M S Smith, and R Surman

Subjects

NEUTRON capture, NUCLEOSYNTHESIS, SUPERNOVAE, NEUTRON cross sections, RARE earth metals, PARTICLES (Nuclear physics)

Abstract

We examine the role of neutron capture on 130Sn during r-process freeze-out in the neutrino-driven wind environment of the core-collapse supernova. We find that the global r-process abundance pattern is sensitive to the magnitude of the neutron capture cross section of 130Sn. The changes to the abundance pattern include not only a relative decrease in the abundance of 130Sn and an increase in the abundance of 131Sn, but also a shift in the distribution of material in the rare earth and third peak regions. [ABSTRACT FROM AUTHOR]

Published

2009

6. Nuclear neutron form factor from neutrino-nucleus coherent elastic scattering.

Author

P S Amanik and G C McLaughlin

Subjects

NEUTRONS, PARTICLES (Nuclear physics), NEUTRINOS, ELASTIC scattering, NUCLEAR counters, PIONS

Abstract

We point out that there is potential to study the nuclear neutron form factor through neutrino nucleus coherent elastic scattering. We determine numbers of events for various scenarios in a liquid noble nuclear recoil detector at a stopped pion neutrino source. [ABSTRACT FROM AUTHOR]

Published

2009

7. The role of neutrinos in r-process nucleosynthesis in supernovae and gamma-ray bursts.

Author

R Surman, J Beun, G C McLaughlin, S Kane, and W R Hix

Subjects

NEUTRINOS, NUCLEOSYNTHESIS, SUPERNOVAE, GAMMA rays

Abstract

The exact astrophysical site of the r-process is uncertain, but the likely candidates--supernovae and compact merger events--are environments with high neutrino fluxes. Here we examine the role of neutrinos in r-process nucleosynthesis under two separate scenarios. In the first, we consider the consequences of a reduction in the electron neutrino flux in a core-collapse supernova environment. We show that such a reduction results in a vigorous r-process with a robust abundance signature due to fission cycling. In the second, we examine the production of r-process nuclei in the outflows from a black hole accretion disk as thought to accompany a merger-type gamma-ray burst (GRB). We use a parameterized outflow model and find the neutrino fluxes emitted from the GRB accretion disk facilitate the synthesis of light r-process nuclei over a broad region of the parameter space explored. [ABSTRACT FROM AUTHOR]

Published

2008