Bound-state effects on light-element abundances in gravitino dark matter scenarios

Richard H. Cyburt, John Ellis, Brian D. Fields, Keith A. Olive, Vassilis C. Spanos

Research output: Contribution to journalReview articlepeer-review

102 Scopus citations

Abstract

If the gravitino is the lightest supersymmetric particle and the long-lived next-to-lightest sparticle (NSP) is the stau, the charged partner of the tau lepton, it may be metastable and form bound states with several nuclei. These bound states may affect the cosmological abundances of 6Li and 7Li by enhancing nuclear rates that would otherwise be strongly suppressed. We consider the effects of these enhanced rates on the final abundances produced in Big-Bang nucleosynthesis (BBN), including injections of both electromagnetic and hadronic energy during and after BBN. We calculate the dominant two- and three-body decays of both neutralino and stau NSPs, and model the electromagnetic and hadronic decay products using the PYTHIA event generator and a cascade equation. Generically, the introduction of bound states drives light element abundances further from their observed values; however, for small regions of parameter space bound-state effects can bring lithium abundances in particular into better accord with observations. We show that in regions where the stau is the NSP with a lifetime longer than 103-104 s, the abundances of 6Li and 7Li are far in excess of those allowed by observations. For shorter lifetimes of order 1000 s, we comment on the possibility in minimal supersymmetric and supergravity models that stau decays could reduce the 7Li abundance from standard BBN values while at the same time enhancing the 6Li abundance.

Original languageEnglish (US)
Article number014
JournalJournal of Cosmology and Astroparticle Physics
Issue number11
DOIs
StatePublished - Nov 1 2006

Keywords

  • Big bang nucleosynthesis
  • Dark matter
  • Physics of the early universe

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