Paper detail

Lightcone Averaging and Precision Cosmology

The first objective of this thesis is to fill the lack in cosmology of a description on the past light cone: the null hypersurface on which observed signals propagate. Its second goal is to evaluate the importance of inhomogeneities in the determination of dark energy parameters, whose real nature is still unknown and for which the influence of matter structures has been proposed as a cosmological alternative. We start with the definition of a "geodesic lightcone" gauge simplifying greatly the study of light propagation in the Universe. We then define a gauge invariant average of scalars on the past light cone and compute the effect of inhomogeneities on the luminosity flux by considering their power spectrum up to its non-linear regime. The effect on the flux is negligible whereas observables like the luminosity distance, computed at second order in perturbations, are much more affected. We also study the distance modulus at the basis of the discovery of dark energy from type Ia supernovae (SNe). The average of this modulus is only slightly affected by inhomogeneities but its variance sensitively depends on them. These results show, within their hypotheses, that an alternative to dark energy by an effect of structures is impossible but, at the same time, emphasize their importance on the dispersion of data in the Hubble diagram. The dominating physical effects turn out to be peculiar velocity of SNe and weak lensing. Our predictions on the dispersion are in very good agreement with first analyses carried out so far to detect a signal of lensing among SNe Ia data and will be testable in the near future.