English

$\beta$-delayed fission in $r$-process nucleosynthesis

Nuclear Theory 2018-12-12 v1 Solar and Stellar Astrophysics

Abstract

We present β\beta-delayed neutron emission and β\beta-delayed fission calculations for heavy, neutron-rich nuclei using the coupled Quasi-Particle Random Phase Approximation plus Hauser-Feshbach (QRPA+HF) approach. From the initial population of a compound nucleus after β\beta-decay, we follow the statistical decay taking into account competition between neutrons, γ\gamma-rays, and fission. We find a region of the chart of nuclides where the probability of β\beta-delayed fission is 100\sim100%, that likely prevents the production of superheavy elements in nature. For a subset of nuclei near the neutron dripline, neutron multiplicity and the probability of fission are both large, leading to the intriguing possibility of multi-chance β\beta-delayed fission, a new decay mode for extremely neutron-rich heavy nuclei. In this new decay mode, β\beta-decay can be followed by multiple neutron emission leading to subsequent daughter generations which each have a probability to fission. We explore the impact of β\beta-delayed fission in rapid neutron capture process (rr-process) nucleosynthesis in the tidal ejecta of a neutron star--neutron star merger and show that it is a key fission channel that shapes the final abundances near the second rr-process peak.

Keywords

Cite

@article{arxiv.1802.04398,
  title  = {$\beta$-delayed fission in $r$-process nucleosynthesis},
  author = {M. R. Mumpower and T. Kawano and T. M. Sprouse and N. Vassh and E. M. Holmbeck and R. Surman and P. Moller},
  journal= {arXiv preprint arXiv:1802.04398},
  year   = {2018}
}

Comments

9 pages, 5 figures, submitted

R2 v1 2026-06-23T00:20:14.277Z