Inflation Driven by Non-Linear Electrodynamics

TL;DR

This paper explores how nonlinear electromagnetic fields can drive cosmic inflation, proposing a new model that avoids initial singularities and aligns with observational data on early universe parameters.

Contribution

It introduces a general f(F) nonlinear electrodynamics framework for cosmology, providing new solutions and detailed phase-space analysis of inflationary dynamics.

Findings

The model predicts a non-singular early universe with accelerated expansion.

Inflationary parameters match observational constraints.

Phase-space analysis reveals stable inflationary solutions.

Abstract

We investigate the inflation driven by a nonlinear electromagnetic field based on an NLED lagrangian density ${\cal L}_{\text{nled}} = - {F} f \left( {F} \right)$, where $f \left( {F}\right)$ is a general function depending on ${F}$. We first formulate an $f$-NLED cosmological model with a more general function $f \left( {F}\right)$ and show that all NLED models can be expressed in this framework; then, we investigate in detail two interesting examples of the function $f \left( {F}\right)$. We present our phenomenological model based on a new Lagrangian for NLED. Solutions to the field equations with the physical properties of the cosmological parameters are obtained. We show that the early Universe had no Big-Bang singularity, which accelerated in the past. We also investigate the qualitative implications of NLED by studying the inflationary parameters, like the slow-roll parameters, spectral index $n_s$, and tensor-to-scalar ratio $r$, and compare our results with observational data. Detailed phase-space analysis of our NLED cosmological model is performed with and without matter source. As a first approach, we consider the motion of a particle of unit mass in an effective potential. Our systems correspond to fast-slow systems for physical values of the electromagnetic field and the energy densities at the end of inflation. We analyze a complementary system using Hubble-normalized variables to investigate the cosmological evolution before the matter-dominated Universe.