The role of noise in the early universe

TL;DR

This paper models the early universe using a quantum system with noise, showing that fluctuations could cause oscillations instead of exponential expansion, highlighting noise's crucial role in cosmic evolution.

Contribution

It introduces a quantum mechanical model with noise to analyze early universe dynamics, revealing how fluctuations can alter expected expansion behavior.

Findings

Noise can stabilize an oscillating universe instead of exponential growth

Quantum fluctuations influence the evolution of the universe's scale factor

Analogies with stochastic Kapitza pendulum illustrate noise effects

Abstract

We consider a quantum mechanical system to model the effect of quantum fields on the evolution of the early universe. The system consists of an inverted oscillator bilinearly coupled to a set of harmonic oscillators. We point out that the role of noise may be crucial in the dynamics of the oscillator, which is analyzed using the theory of harmonic oscillators with random frequency. Using this analogy we argue that, due to the fluctuations around its mean value, a positive vacuum energy density would not produce an exponentially expanding but an oscillating universe, in the same fashion that an inverted pendulum is stabilized by random oscillations of the suspension point (stochastic Kapitza pendulum). The results emphasize the relevance of noise in the evolution of the scale factor.