Big Bang nucleosynthesis with a stiff fluid
Abstract
Models that lead to a cosmological stiff fluid component, with a density that scales as , where is the scale factor, have been proposed recently in a variety of contexts. We calculate numerically the effect of such a stiff fluid on the primordial element abundances. Because the stiff fluid energy density decreases with the scale factor more rapidly than radiation, it produces a relatively larger change in the primordial helium-4 abundance than in the other element abundances, relative to the changes produced by an additional radiation component. We show that the helium-4 abundance varies linearly with the density of the stiff fluid at a fixed fiducial temperature. Taking and to be the stiff fluid energy density and the standard density in relativistic particles, respectively, at MeV, we find that the change in the primordial helium abundance is well-fit by . The changes in the helium-4 abundance produced by additional radiation or by a stiff fluid are identical when these two components have equal density at a "pivot temperature", , where we find MeV. Current estimates of the primordial He abundance give the constraint on a stiff fluid energy density of .
Cite
@article{arxiv.1006.4166,
title = {Big Bang nucleosynthesis with a stiff fluid},
author = {Sourish Dutta and Robert J. Scherrer},
journal= {arXiv preprint arXiv:1006.4166},
year = {2010}
}
Comments
6 pages, 2 figures. Clarification added: element abundances derived using a full numerical calculation. Version accepted at PRD