The Neutron Mean Life and Big Bang Nucleosynthesis

Abstract

We explore the effect of neutron lifetime and its uncertainty on standard big-bang nucleosynthesis (BBN). BBN describes the cosmic production of the light nuclides 1 H, D, 3 H+3 He, 4 He, and 7 Li+7 Be in the first minutes of cosmic time. The neutron mean life τn has two roles in modern BBN calculations: (1) it normalizes the matrix element for weak n p interconversions, and (2) it sets the rate of free neutron decay after the weak interactions freeze out. We review the history of the interplay between τn measurements and BBN, and present a study of the sensitivity of the light element abundances to the modern neutron lifetime measurements. We find that τn uncertainties dominate the predicted 4 He error budget, but these theory errors remain smaller than the uncertainties in 4 He observations, even with the dispersion in recent neutron lifetime measurements. For the other light-element predictions, τn contributes negligibly to their error budget. Turning the problem around, we combine present BBN and cosmic microwave background (CMB) determinations of the cosmic baryon density to predict a "cosmologically preferred" mean life of τn( BBN+CMB) = 870 16 \ sec, which is consistent with experimental mean life determinations. We go on to show that if future astronomical and cosmological helium observations can reach an uncertainty of σ obs(Yp) = 0.001 in the 4 He mass fraction Yp, this could begin to discriminate between the mean life determinations.