Sensitivity studies for the weak r process: Neutron capture rates

R. Surman; M. Mumpower; R. Sinclair; K. L. Jones; W. R. Hix; G. C. McLaughlin

doi:10.1063/1.4867191

Sensitivity studies for the weak r process: Neutron capture rates

R. Surman
, M. Mumpower
, R. Sinclair
, K. L. Jones
, W. R. Hix
, G. C. McLaughlin

Theoretical and Computational Physics

Research output: Contribution to journal › Article › peer-review

49 Scopus citations

Abstract

Rapid neutron capture nucleosynthesis involves thousands of nuclear species far from stability, whose nuclear properties need to be understood in order to accurately predict nucleosynthetic outcomes. Recently sensitivity studies have provided a deeper understanding of how the r process proceeds and have identified pieces of nuclear data of interest for further experimental or theoretical study. A key result of these studies has been to point out the importance of individual neutron capture rates in setting the final r-process abundance pattern for a 'main' (A ∼ 130 peak and above) r process. Here we examine neutron capture in the context of a 'weak' r process that forms primarily the A ∼ 80 r-process abundance peak. We identify the astrophysical conditions required to produce this peak region through weak r-processing and point out the neutron capture rates that most strongly influence the final abundance pattern.

Original language	English
Article number	041008
Journal	AIP Advances
Volume	4
Issue number	4
DOIs	https://doi.org/10.1063/1.4867191
State	Published - Apr 2014

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abstract = "Rapid neutron capture nucleosynthesis involves thousands of nuclear species far from stability, whose nuclear properties need to be understood in order to accurately predict nucleosynthetic outcomes. Recently sensitivity studies have provided a deeper understanding of how the r process proceeds and have identified pieces of nuclear data of interest for further experimental or theoretical study. A key result of these studies has been to point out the importance of individual neutron capture rates in setting the final r-process abundance pattern for a 'main' (A ∼ 130 peak and above) r process. Here we examine neutron capture in the context of a 'weak' r process that forms primarily the A ∼ 80 r-process abundance peak. We identify the astrophysical conditions required to produce this peak region through weak r-processing and point out the neutron capture rates that most strongly influence the final abundance pattern.",

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T2 - Neutron capture rates

AU - Surman, R.

AU - Mumpower, M.

AU - Sinclair, R.

AU - Jones, K. L.

AU - Hix, W. R.

AU - McLaughlin, G. C.

PY - 2014/4

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AB - Rapid neutron capture nucleosynthesis involves thousands of nuclear species far from stability, whose nuclear properties need to be understood in order to accurately predict nucleosynthetic outcomes. Recently sensitivity studies have provided a deeper understanding of how the r process proceeds and have identified pieces of nuclear data of interest for further experimental or theoretical study. A key result of these studies has been to point out the importance of individual neutron capture rates in setting the final r-process abundance pattern for a 'main' (A ∼ 130 peak and above) r process. Here we examine neutron capture in the context of a 'weak' r process that forms primarily the A ∼ 80 r-process abundance peak. We identify the astrophysical conditions required to produce this peak region through weak r-processing and point out the neutron capture rates that most strongly influence the final abundance pattern.

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Sensitivity studies for the weak r process: Neutron capture rates

Abstract

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