Power Law Plateau Inflation and Primary Gravitational Waves in the light of ACT

TL;DR

This paper explores Power-Law Plateau inflation models' compatibility with ACT data, analyzes reheating dynamics and gravitational waves, and establishes bounds on reheating temperature and e-folds for observational viability.

Contribution

It demonstrates that Power-Law Plateau inflation remains viable with ACT data and links reheating parameters to gravitational wave spectra and observational constraints.

Findings

PLP inflation consistent with ACT DR6 data across parameter space

Reheating temperature bounds depend on the equation of state

Gravitational wave spectrum detection likelihood varies with reheating parameters

Abstract

We investigate Power-Law Plateau (PLP) inflation in standard gravity and its consistency with ACT DR6 data. While many inflationary models, including the Starobinsky inflation, are disfavored by ACT observations, the PLP potential remains viable across a broad range of its parameters. Then, the dynamics of the reheating phase are investigated, where we mainly focus on the reheating temperature and its relationship with the inflationary phase and primordial gravitational waves. Incorporating the overproduction of the primordial gravitational waves can affect the effective number of relativistic species during the bounce. The constraint data on $\Delta N_{\rm eff}$ can impose a lower bound on the reheating temperature. This constraint will be more efficient for a stiff equation of state. It is determined that for $\omega_{re} > 0.58$, this constraint would be efficient. Combining the result of the reheating temperature and the inflationary phase, it is concluded that to have both a viable result standing in $1\sigma$ of ACT DR6 and also to satisfy the reheating lower bound, the total number of e-folds during the inflationary phase should be $N_k \lesssim 62$. Higher e-folds of expansion result in a reheating temperature below the bound, which is disfavored. Finally, for the constraint values of the reheating temperature, the energy spectrum of the gravitational waves has been explored. The results indicate that there is a higher chance of detection for lower reheating temperatures and higher reheating equation of state.