Professor Pedro Ferreira

Errors in Estimating Omega_Lambda due to the Fluid Approximation

ArXiv 0908.4488 (2009)

Authors:

Timothy Clifton, Pedro G Ferreira

Abstract:

The matter content of the Universe is strongly inhomogeneous on small scales. Motivated by this fact, we consider a model of the Universe that has regularly spaced discrete masses, rather than a continuous fluid. The optical properties of such space-times can differ considerably from the continuous fluid case, even if the 'average' dynamics are the same. We show that these differences have consequences for cosmological parameter estimation, and that fitting to recent supernovae observations gives a correction to the inferred value of Omega_Lambda of ~10%.

Archipelagian Cosmology: Dynamics and Observables in a Universe with Discretized Matter Content

(2009)

Authors:

Timothy Clifton, Pedro G Ferreira

Archipelagian Cosmology: Dynamics and Observables in a Universe with Discretized Matter Content

ArXiv 0907.4109 (2009)

Authors:

Timothy Clifton, Pedro G Ferreira

Abstract:

We consider a model of the Universe in which the matter content is in the form of discrete islands, rather than a continuous fluid. In the appropriate limits the resulting large-scale dynamics approach those of a Friedmann-Robertson-Walker (FRW) universe. The optical properties of such a space-time, however, do not. This illustrates the fact that the optical and `average' dynamical properties of a relativistic universe are not equivalent, and do not specify each other uniquely. We find the angular diameter distance, luminosity distance and redshifts that would be measured by observers in these space-times, using both analytic approximations and numerical simulations. While different from their counterparts in FRW, the effects found do not look like promising candidates to explain the observations usually attributed to the existence of Dark Energy. This incongruity with standard FRW cosmology is not due to the existence of any unexpectedly large structures or voids in the Universe, but only to the fact that the matter content of the Universe is not a continuous fluid.

What the small angle CMB really tells us about the curvature of the Universe

(2009)

Authors:

Timothy Clifton, Pedro G Ferreira, Joe Zuntz

What the small angle CMB really tells us about the curvature of the Universe

ArXiv 0902.1313 (2009)

Authors:

Timothy Clifton, Pedro G Ferreira, Joe Zuntz

Abstract:

It is well known that observations of the cosmic microwave background (CMB) are highly sensitive to the spatial curvature of the Universe, k. Here we find that what is in fact being tightly constrained by small angle fluctuations is spatial curvature near the surface of last scattering, and that if we allow k to be a function of position, rather than taking a constant value everywhere, then considerable spatial curvature is permissible within our own locale. This result is of interest for the giant void models that attempt to explain the supernovae observations without Dark Energy. We find voids models with a homogeneous big bang can be compatible with the observed small angle CMB, but only if they exist in a positively curved universe. To be compatible with local measurements of H_0, however, we find that a radially varying bang time is required.