Cosmological constraints on Ho\v{r}ava gravity revised in light of GW170817 and GRB170817A and the degeneracy with massive neutrinos

TL;DR

This paper revises cosmological bounds on Hořava gravity considering gravitational wave speed constraints and explores degeneracies with massive neutrinos, leading to tighter parameter limits and insights into neutrino mass effects.

Contribution

It provides updated constraints on Hořava gravity parameters incorporating GW170817 data and analyzes neutrino degeneracies using multiple cosmological observations.

Findings

Gravitational wave speed constraints restrict Hořava gravity parameters.

Massive neutrinos can offset modifications in CMB and lensing spectra.

Joint data analysis favors zero neutrino mass, tightening gravity model bounds.

Abstract

We revise the cosmological bounds on Ho\v{r}ava gravity taking into accounts the stringent constraint on the speed of propagation of gravitational waves from GW170817 and GRB170817A. In light of this we also investigate the degeneracy between massive neutrinos and Ho\v{r}ava gravity. We show that a luminal propagation of gravitational waves suppresses the large-scale Cosmic Microwave Background (CMB) radiation temperature anisotropies and the presence of massive neutrinos increases this effect. On the contrary large neutrinos mass can compensate the modifications induced by Ho\v{r}ava gravity in the lensing, matter and primordial B-mode power spectra. Another degeneracy is found, at theoretical level, between the tensor-to-scalar ratio $r$ and massive neutrinos as well as with the model's parameters. We analyze these effects using CMB, supernovae type Ia (SNIa), galaxy clustering and weak gravitational lensing measurements and we show how such degeneracies are removed. We find that the model's parameters are constrained to be very close to their General Relativity limits and we get a two orders of magnitude improved upper bound, with respect to the Big Bang Nucleosynthesis constraint, on the deviation of the effective gravitational constant from the Newtonian one. The deviance information criterion suggests that in Ho\v{r}ava gravity $\Sigma m_\nu>0$ is favored when CMB data only are considered, while the joint analysis of all datasets prefers zero neutrinos mass.