Litcius/Paper detail

Determining Model-independent H<sub>0</sub> and Consistency Tests

Kai Liao, Arman Shafieloo, Ryan E. Keeley, Eric V. Linder

2020The Astrophysical Journal Letters76 citationsDOIOpen Access PDF

Abstract

Abstract We determine the Hubble constant H 0 precisely (2.3% uncertainty) in a manner independent of the cosmological model through Gaussian process regression, using strong lensing and supernova data. Strong gravitational lensing of a variable source can provide a time-delay distance D Δ t and angular diameter distance to the lens D d . These absolute distances can anchor Type Ia supernovae, which give an excellent constraint on the shape of the distance–redshift relation. Updating our previous results to use the H0LiCOW program’s milestone data set consisting of six lenses, four of which have both D Δ t and D d measurements, we obtain for a flat universe and for a non-flat universe. We carry out several consistency checks on the data and find no statistically significant tensions, though a noticeable redshift dependence persists in a particular systematic manner that we investigate. Speculating on the possibility that this trend of derived Hubble constant with lens distance is physical, we show how this can arise through modified gravity light propagation, which would also impact the weak lensing σ 8 tension.

Topics & Concepts

Hubble's lawConsistency (knowledge bases)Gravitational lensStrong gravitational lensingPhysicsWeak gravitational lensingLens (geology)RedshiftConstant (computer programming)Gravitational lensing formalismConstraint (computer-aided design)MathematicsCosmologyGaussian processAngular diameterDark energyGaussianAstrophysicsCosmological constantDistance modulusType (biology)Set (abstract data type)Data setGravitationTerm (time)Cosmology and Gravitation TheoriesGamma-ray bursts and supernovaeParticle physics theoretical and experimental studies
Determining Model-independent H<sub>0</sub> and Consistency Tests | Litcius