Smooth Beginning of the Universe

TL;DR

This paper explores the initial conditions of the universe using differential spaces theory, defining a smooth beginning and analyzing models consistent with supernova observations.

Contribution

It introduces a novel framework for modeling the universe's beginning with differential spaces and identifies models compatible with observational data.

Findings

Identified three types of cosmological fluids capable of smooth evolution.

Found models consistent with type Ia supernovae data.

Defined the concept of a smooth universe beginning using differential spaces.

Abstract

The breaking down of the equivalence principle, when discussed in the context of Sikorski's differential spaces theory, leads to the definition of the so-called differentially singular boundary (d-boundary) and to the concept of differential space with singularity associated with a given space-time differential manifold. This enables us to define the time orientability, the beginning of the cosmological time and the smooth evolution for the flat Friedmanian world model with the initial singularity. The simplest smoothly evolved models are studied. It is shown, that the cosmological matter causing such an evolution can be of three different types. One of them is the fluid with dark energy properties, the second the fluid with attraction properties, and the third a mixture of the other two. Among all investigated smoothly evolved solutions, models qualitatively consistent with the observational data of type Ia supernovae have been found.