The Three Faces of Omegam: Testing Gravity with Low and High Redshift SN Ia Surveys

Abstract

Peculiar velocities of galaxies hosting Type Ia supernovae generate a significant systematic effect in deriving the dark energy equation of state w, at level of a few percent. Here we illustrate how the peculiar velocity effect in SN Ia data can be turned from a 'systematic' into a probe of cosmological parameters. We assume a flat Lambda-Cold Dark Matter model (w=-1) and use low and high redshift SN Ia data to derive simultaneously three distinct estimates of the matter density Omegam which appear in the problem: from the geometry, from the dynamics and from the shape of the matter power spectrum. We find that each of the three Omegam's agree with the canonical value Omegam=0.25 to within 1 sigma, for reasonably assumed fluctuation amplitude and Hubble parameter. This is consistent with the standard cosmological scenario for both the geometry and the growth of structure. For fixed Omegam = 0.25 for all three Omegam's, we constrain gamma = 0.72 +/- 0.21 in the growth factor Omegam(z)gamma, so we cannot currently distinguish between standard Einstein gravity and predictions from some modified gravity models. Future surveys of thousands of SN Ia, or inclusion of peculiar velocity data, could significantly improve the above tests.