Characterizing the post-inflationary reheating history, Part II: Multiple interacting daughter fields

Abstract

We characterize the post-inflationary dynamics of an inflaton φ coupled to multiple interacting daughter fields Xn (n=1,… Nd) through quadratic-quadratic interactions gn 2φ2 Xn2. We assume a monomial inflaton potential V(φ) |φ|p (p ≥ 2) around the minimum. By simulating the system in 2+1-dimensional lattices, we study the post-inflationary evolution of the energy distribution and equation of state, from the end of inflation until a stationary regime is achieved. We show that in this scenario, the energy transferred to the daughter field sector can be larger than 50\%, surpassing this way the upper bound found previously for single daughter field models. In particular, for p ≥ 4 the energy at very late times is equally distributed between all fields, and only 100/(Nd + 1) \% of the energy remains in the inflaton. We also consider scenarios in which the daughter fields have scale-free interactions λnm Xn2 Xm2, including the case of quartic daughter field self-interactions (for n=m). We show that these interactions trigger a resonance process during the non-linear regime, which in the single daughter field case already allows to deplete more than 50\% of the energy from the inflaton for p≥ 4.