Relativistic Fractal Cosmologies

TL;DR

This paper explores relativistic fractal cosmologies using Lemaitre-Tolman solutions to model galaxy distribution inhomogeneities, showing some models align with observational constraints and discussing implications for cosmological models.

Contribution

It introduces a relativistic fractal cosmology framework based on Lemaitre-Tolman solutions, connecting Newtonian fractal ideas with Einstein's equations and observational data.

Findings

Fractal solutions can match observed density decay and fractal dimensions.

Friedmann models appear inhomogeneous along the past light cone when observationally interpreted.

The Einstein-de Sitter model can be interpreted as having zero global density.

Abstract

This article reviews an approach for constructing a simple relativistic fractal cosmology whose main aim is to model the observed inhomogeneities of the distribution of galaxies by means of the Lemaitre-Tolman solution of Einstein's field equations for spherically symmetric dust in comoving coordinates. This model is based on earlier works developed by L. Pietronero and J.R. Wertz on Newtonian cosmology, whose main points are discussed. Observational relations in this spacetime are presented, together with a strategy for finding numerical solutions which approximate an averaged and smoothed out single fractal structure in the past light cone. Such fractal solutions are shown, with one of them being in agreement with some basic observational constraints, including the decay of the average density with the distance as a power law (the de Vaucouleurs' density power law) and the fractal dimension in the range 1 <= D <= 2. The spatially homogeneous Friedmann model is discussed as a special case of the Lemaitre-Tolman solution, and it is found that once we apply the observational relations developed for the fractal model we find that all Friedmann models look inhomogeneous along the backward null cone, with a departure from the observable homogeneous region at relatively close ranges. It is also shown that with these same observational relations the Einstein-de Sitter model can have an interpretation where it has zero global density, a result consistent with the "zero global density postulate" advanced by Wertz for hierarchical cosmologies and conjectured by Pietronero for fractal cosmological models. The article ends with a brief discussion on the possible link between this model and nonlinear and chaotic dynamics.