Characterizing the post-inflationary reheating history, Part I: single daughter field with quadratic-quadratic interaction
Abstract
We study the evolution of the energy distribution and equation of state of the Universe from the end of inflation until the onset of either radiation domination (RD) or a transient period of matter domination (MD). We use both analytical techniques and lattice simulations. We consider two-field models where the inflaton has a monomial potential after inflation V() | - v|p (p≥2), and is coupled to a daughter field X through a quadratic-quadratic interaction g22 X2. We consider two situations, depending on whether the potential has a minimum at i) v = 0, or ii) v > 0. In the scenario i), the final energy transferred to X is independent of g2 and entirely determined by p: it is negligible for p < 4, and of order 50\% for p ≥ 4. The system goes to MD at late times for p = 2, while it goes to RD for p > 2. In the later case, we can calculate exactly the number of e-folds until RD as a function of g2, and hence predict accurately inflationary observables like the scalar tilt ns and the tensor-to-scalar ratio r. In the scenario ii), the energy is always transferred completely to X for p>2, as long as its effective mass mX2 = g2(-v)2 is not negligible. For p=2, the final ratio between the energy densities of X and depends strongly on g2. For all p 2, the system always goes to MD at late times.
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