Partial Differential Equations with Random Noise in Inflationary Cosmology

TL;DR

This paper investigates how random noise influences parametric resonance in inflationary cosmology, revealing that noise can enhance instability and providing a new proof of Anderson localization.

Contribution

The study demonstrates that specific idealized noise amplifies parametric resonance instability, offering new insights into early universe dynamics and a novel proof of Anderson localization.

Findings

Noise enhances parametric resonance instability.

A new proof of Anderson localization is provided.

Noise can make the instability more effective.

Abstract

Random noise arises in many physical problems in which the observer is not tracking the full system. A case in point is inflationary cosmology, the current paradigm for describing the very early universe, where one is often interested only in the time-dependence of a subsystem. In inflationary cosmology it is assumed that a slowly rolling scalar field leads to an exponential increase in the size of space. At the end of this phase, the scalar field begins to oscillate and transfers its energy to regular matter. This transfer typically involves a parametric resonance instability. This article reviews work which the author has done in collaboration with Walter Craig studying the role which random noise can play in the parametric resonance instability of matter fields in the presence of the oscillatory inflaton field. We find that the particular idealized form of the noise studied here renders the instability more effective. As a corollary, we obtain a new proof of Anderson localization.