Inflationary Phenomenology of Einstein Gauss-Bonnet Gravity Compatible with GW170817

TL;DR

This paper explores Einstein Gauss-Bonnet gravity models compatible with GW170817, demonstrating how to constrain the scalar coupling to ensure gravitational wave speed equals light speed, and analyzing inflationary phenomenology consistent with observational data.

Contribution

It introduces conditions on scalar couplings in Einstein Gauss-Bonnet theories to match gravitational wave speed with light speed and studies their inflationary implications.

Findings

Gravitational wave speed can be set to unity with specific scalar coupling constraints.

Power-law inflation models can fit Planck 2018 data within this framework.

String-corrected extensions can also achieve the correct gravitational wave speed.

Abstract

In this work we shall study Einstein Gauss-Bonnet theories and we investigate when these can have their gravitational wave speed equal to the speed of light, which is unity in natural units, thus becoming compatible with the striking event GW170817. We demonstrate how this is possible and we show that if the scalar coupling to the Gauss-Bonnet invariant is constrained to satisfy a differential equation, the gravitational wave speed becomes equal to one. Accordingly, we investigate the inflationary phenomenology of the resulting restricted Einstein Gauss-Bonnet model, by assuming that the slow-roll conditions hold true. As we demonstrate, the compatibility with the observational data coming from the Planck 2018 collaboration, can be achieved, even for a power-law potential. We restricted ourselves to the study of the power-law potential, due to the lack of analyticity, however more realistic potentials can be used, in this case though the calculations are not easy to be performed analytically. We also pointed out that a string-corrected extension of the Einstein Gauss-Bonnet model we studied, containing terms of the form $\sim \xi(\phi) G^{ab}\partial_a\phi \partial_b \phi $ can also provide a theory with gravity waves speed $c_T^2=1$ in natural units, if the function $\xi(\phi)$ is appropriately constrained, however in the absence of the Gauss-Bonnet term $\sim \xi(\phi) \mathcal{G}$ the gravity waves speed can never be $c_T^2=1$. Finally, we discuss which extensions of the above models can provide interesting cosmologies, since any combination of $f(R,X,\phi)$ gravities with the above string-corrected Einstein Gauss-Bonnet models can yield $c_T^2=1$, with $X=\frac{1}{2}\partial_{\mu}\phi\partial^{\mu}\phi $.