The Effective Fluid Approach to Cosmological Nonlinearities: Applications to Preheating

TL;DR

This paper extends the effective fluid approach to cosmological nonlinearities to include pressure effects and non-Newtonian gravity, applying it specifically to the preheating phase after inflation, and derives relevant equations of motion.

Contribution

It introduces a generalized formalism for long-wavelength perturbations that accounts for pressure and non-Newtonian gravity, improving upon previous pressureless, Newtonian assumptions.

Findings

Differences found when relaxing previous assumptions, even with zero pressure.

Derived equations of motion for density perturbations and velocities during preheating.

Presented linearized Einstein equations for long-wavelength metric perturbations.

Abstract

In [arXiv:1004.2488], Baumann et al. present a new formalism for studying cosmological systems where the characteristic scale of non-linearities is much smaller than the Hubble scale. By integrating out the short-wavelength modes, it is possible to obtain an effective theory of long-wavelength perturbations that is described by an imperfect fluid evolving in an FRW background. As the long-wavelength perturbations remain small even when the short-scale dynamics are non-linear, the tools of linear perturbation theory may be applied. The work in [arXiv:1004.2488] deals only with matter in the form of a pressureless perfect fluid with zero anisotropic stress, and also assumes that the short-scale gravitational dynamics are Newtonian. In this work we extend this formalism to the case of a perfect fluid with pressure, and in particular to the case of preheating after inflation, where the matter content of the universe can be modeled by two coupled scalar fields. We discard the assumption that the short-scale gravitational dynamics are Newtonian. We find that our results differ from Baumann et al.'s even when the pressure is set to zero, which suggests that relaxing their assumptions creates appreciable changes in the long-wavelength effective theory. We derive equations of motion for the total density perturbation and matter velocities during preheating, as well as linearized Einstein equations for the long-wavelength metric perturbations. We also present the equations governing the effective long-wavelength scalar field dynamics.