Reevaluating the cosmological redshift: insights into inhomogeneities and irreversible processes

TL;DR

This paper presents a covariant approach to cosmological redshift, revealing how irreversible processes and entropy production influence the universe's expansion and mimic dark energy effects.

Contribution

It introduces a covariant method for redshift calculation that accounts for inhomogeneities and irreversible processes, challenging standard assumptions about volume expansion.

Findings

Irreversible processes lead to a dominance of void expansion in the averaged volume.

Entropy production acts like a dynamical dark energy component.

Covariant approach clarifies the role of inhomogeneities in cosmic expansion.

Abstract

Understanding the expansion of the Universe remains a profound challenge in fundamental physics. The complexity of solving General Relativity equations in the presence of intricate, inhomogeneous flows has compelled cosmological models to rely on perturbation theory in a homogeneous FLRW background. This approach accounts for a redshift of light encompassing contributions from both the cosmological background expansion along the photon's trajectory and Doppler effects at emission due to peculiar motions. However, this computation of the redshift is not covariant, as it hinges on specific coordinate choices that may distort physical interpretations of the relativity of motion. In this study, we show that peculiar motions, when tracing the dynamics along time-like geodesics, must contribute to the redshift of light through a local volume expansion factor, in addition to the background expansion. By employing a covariant approach to redshift calculation, we address the central question of whether the cosmological principle alone guarantees that the averaged local volume expansion factor matches the background expansion. We establish that this holds true only in scenarii characterized by a reversible evolution of the Universe, where inhomogeneous expansion and compression modes mutually compensate. In the presence of irreversible processes, such as the dissipation of large-scale compression modes through matter virialization and associated entropy production, the averaged expansion factor becomes dominated by expansion in voids that cannot be compensated anymore by compression in virialized structures. Our approach shows that entropy production due to irreversible processes during the formation of structures plays the same role as an effective, time-dependent cosmological constant, i.e. dynamical dark energy, without the need to invoke new unknown physics.