Testing quantum gravity with primordial gravitational waves

TL;DR

This paper proposes a testable alternative to inflation based on quantum gravity theories with Weyl invariance, predicting specific signatures in primordial gravitational waves and scalar spectra that can be observed with upcoming experiments.

Contribution

It introduces a novel inflation alternative rooted in quantum gravity with Weyl invariance, predicting observable gravitational wave signatures and constraining the fundamental energy scale.

Findings

Predicts a scalar spectral index consistent with observations.

Forecasts a detectable tensor-to-scalar ratio around 0.01.

Establishes a lower bound on the fundamental energy scale at 8.5×10^{10} GeV.

Abstract

We propose a testable alternative to inflation directly built in a very general class of ultraviolet complete theories of quantum gravity enjoying Weyl invariance. After the latter is spontaneously broken, logarithmic quantum corrections to the action make both the primordial tensor spectrum (from graviton fluctuations) and the scalar spectrum (from thermal fluctuations) quasi scale invariant. We predict a scalar spectral index $n_{\rm s}$ which only depends on two parameters and is consistent with observations, a tensor index $n_{\rm t} =1-n_{\rm s}>0$, and, if the fundamental energy scale of the theory $\Lambda_*=M_{\textrm{Pl}}$ is of order of the Planck mass, a tensor-to-scalar ratio $r_{0.05}\approx 0.01$ detectable by BICEP Array and LiteBIRD in the immediate or near future, respectively, and a blue-tilted stochastic gravitational-wave background observable by DECIGO in the further future. From the observational constraint $r_{0.05}<0.036$, we also find the lower bound $\Lambda_*> 8.5\times 10^{10}\,{\rm GeV}$, much stronger than any previous one for this class of theories.