Particle decay in post inflationary cosmology

Abstract

We study scalar particle decay during the radiation and matter dominated epochs of a standard cosmological model. An adiabatic approximation is introduced that is valid for degrees of freedom with typical wavelengths much smaller than the particle horizon (~Hubble radius) at a given time. We implement a non-perturbative method that includes the cosmological expansion and obtain a cosmological Fermi's Golden Rule that enables one to compute the decay law of a parent particle of mass m1, along with the build up of the population of daughter particles of mass m2. The survival probability of the decaying particle is P(t)=e-k(t)\,t with k(t) being an effective momentum and time dependent decay rate. It features a transition time scale tnr between the relativistic and non-relativistic regimes and for k ≠ 0 is always smaller than the analogous rate in Minkowski spacetime, as a consequence of (local) time dilation and the cosmological redshift. For t tnr the decay law is a "stretched exponential" P(t) = e-(t/t*)3/2, whereas for the non-relativistic stage with t tnr, we find P(t) = e-0 t\,(t/tnr)0\,tnr/2. The Hubble time scale 1/H(t) introduces an energy uncertainty E H(t) which relaxes the constraints of kinematic thresholds. This opens new decay channels into heavier particles for 2π Ek(t) H(t) 4m22-m21, with Ek(t) the (local) comoving energy of the decaying particle. As the expansion proceeds this channel closes and the usual two particle thresholds restrict the decay kinematics.