Multiscale cosmology and structure-emerging Dark Energy: A plausibility analysis

Abstract

Cosmological backreaction suggests a link between structure formation and the expansion history of the Universe. In order to quantitatively examine this connection, we dynamically investigate a volume partition of the Universe into over-- and underdense regions. This allows us to trace structure formation using the volume fraction of the overdense regions λ as its characterizing parameter. Employing results from cosmological perturbation theory and extrapolating the leading mode into the nonlinear regime, we construct a three--parameter model for the effective cosmic expansion history, involving λ_0, the matter density m0, and the Hubble rate H_0 of today's Universe. Taking standard values for m0 and H_0 as well as a reasonable value for λ_0, that we derive from N--body simulations, we determine the corresponding amounts of backreaction and spatial curvature. We find that the obtained values that are sufficient to generate today's structure also lead to a --like behavior of the scale factor, parametrized by the same parameters m0 and H_0, but without a cosmological constant. However, the temporal behavior of λ does not faithfully reproduce the structure formation history. Surprisingly, however, the model matches with structure formation with the assumption of a low matter content, m0≈3\%, a result that hints to a different interpretation of part of the backreaction effect as kinematical Dark Matter. (truncated)