Canonical Scalar Field Inflation with String and $R^2$-Corrections

TL;DR

This paper investigates how string and $f(R)$ gravity corrections influence scalar field inflation, ensuring gravitational wave speed matches light, and demonstrates the model's viability across various parameters.

Contribution

It introduces a combined framework of string and $f(R)$ corrections in scalar inflation, deriving relations between model functions and analyzing inflationary phenomenology.

Findings

Model can produce viable inflationary predictions.

When $ ext{alpha}<10^{-3}$, $R^2$ effects are negligible but dynamics differ.

Scalar potential and coupling functions are interconnected.

Abstract

Assuming that a scalar field controls the inflationary era, we examine the combined effects of string and $f(R)$ gravity corrections on the inflationary dynamics of canonical scalar field inflation, imposing the constraint that the speed of the primordial gravitational waves is equal to that of light's. Particularly, we study the inflationary dynamics of an Einstein-Gauss-Bonnet gravity in the presence of $\alpha R^2$ corrections, where $\alpha$ is a free coupling parameter. As it was the case in the pure Einstein-Gauss-Bonnet gravity, the realization that the gravitational waves propagate through spacetime with the velocity of light, imposes the constraint that the Gauss-Bonnet coupling function $\xi(\phi)$ obeys the differential equation $\ddot\xi=H\dot\xi$, where $H$ is the Hubble rate. Subsequently, a relation for the time derivative of the scalar field is extracted which implies that the scalar functions of the model, which are the Gauss-Bonnet coupling and the scalar potential, are interconnected and simply designating one of them specifies the other immediately. In this framework, it is useful to freely designate $\xi(\phi)$ and extract the corresponding scalar potential from the equations of motion but the opposite is still feasible. We demonstrate that the model can produce a viable inflationary phenomenology and for a wide range of the free parameters. Also, a mentionable issue is that when the coupling parameter $\alpha$ of the $R^2$ correction term is $\alpha<10^{-3}$ in Planck Units, the $R^2$ term is practically negligible and one obtains the same equations of motion as in the pure Einstein-Gauss-Bonnet theory, however the dynamics still change, since now the time derivative of $\frac{\partial f}{\partial R}$ is nonzero.