Cosmic acceleration as a saddle-node bifurcation: background identities and structure

TL;DR

This paper models the universe's late-time acceleration as a saddle-node bifurcation in the Friedmann system, linking it to non-equilibrium dynamics and eliminating the need for dark energy.

Contribution

It introduces a bifurcation-theoretic framework for cosmic acceleration, showing robustness and structural stability without extra fields or dark energy.

Findings

Acceleration arises from a saddle-node bifurcation in the dynamical system.

Normal form analysis reveals robustness of the bifurcation.

Linking acceleration to non-equilibrium evolution rather than a cosmological constant.

Abstract

We show that the late-time acceleration of the universe can be understood as a codimension-one bifurcation of the Friedmann dynamical system in the variables $(H,\Omega)$. At a critical value of the density-parameter combination, a saddle-node bifurcation occurs; beyond the saddle-node, trajectories are globally attracted to a new accelerating fixed point. We obtain a normal form and a versal unfolding for the reduced dynamics, proving robustness (structural stability) of the phenomenon and deriving the characteristic square-root splitting of the emerging equilibria. We interpret the unfolding parameter as a measure of departure from adiabaticity via a modified continuity/entropy balance, thus linking acceleration to controlled non-equilibrium evolution rather than to a cosmological constant. In particular, late-time acceleration arises without invoking a separate dark-energy fluid; it emerges from a bounded unfolding of the background flow around a saddle-node organizing center. We situate this within a broader "general-relativity landscape," where control parameters act as moduli and branches of exact solutions appear as equilibrium loci, allowing bifurcation-theoretic tools to organize cosmological dynamics without introducing extra fields, and suggesting a coherent, bifurcation-guided cosmic history.