Relaxing the Big-bang Bound to the Baryon Density

Abstract

In the standard picture of big-bang nucleosynthesis the yields of D, 3He, 4He, and 7Li only agree with their inferred primordial abundances if the fraction of critical density contributed by baryons is between 0.01h-2 and 0.02h-2 (h is the present value of the Hubble constant in units of 100-1). This is the basis of the very convincing and important argument that baryons can contribute at most 10\% of critical density and thus cannot close the Universe. Nonstandard scenarios involving decaying particles,1 inhomogeneities in the baryon density,2 and even more exotic ideas3 put forth to evade this bound have been largely unsuccessful.4 We suggest a new way of relaxing the bound: If the tau neutrino has a mass of 20-30 and lifetime of 200 -1000, and its decay products include electron neutrinos, the bound to the baryon mass density can be loosened by a about factor of 10. The key is the decay-generated electron antineutrinos: around the time of nucleosynthesis they are captured by protons to produce neutrons, thereby changing the outcome of nucleosynthesis. Experiments at e colliders should soon be sensitive to a tau-neutrino mass in the required range.

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