Primordial fluctuations without scalar fields
Abstract
We revisit the question of whether fluctuations in hydrodynamical, adiabatical matter could explain the observed structures in our Universe. We consider matter with variable equation of state and a concomitant (under the adiabatic assumption) density dependent speed of sound, . We find a limited range of possibilities for a set up when modes start inside the Hubble radius, then leaving it and freezing out. For expanding Universes, power-law models are ruled out (except when , requiring post-stretching the seeded fluctuations); but sharper profiles in do solve the horizon problem. Among these, a phase transition in is notable for leading to scale-invariant fluctuations if the initial conditions are thermal. For contracting Universes all power-law solve the horizon problem, but only one leads to scale-invariance: and . This model bypasses a number of problems with single scalar field cyclic models (for which is large but constant).
Cite
@article{arxiv.0907.1772,
title = {Primordial fluctuations without scalar fields},
author = {J. Magueijo and J. Noller},
journal= {arXiv preprint arXiv:0907.1772},
year = {2010}
}