Measuring Coherent Motions in the Universe

TL;DR

This paper measures galaxy motions using large-scale redshift distortions, providing results consistent with LCDM predictions and challenging alternative models, while highlighting potential local density effects.

Contribution

Introduces a new methodology for estimating galaxy coherent motions that reduces dependence on galaxy bias and cosmological model assumptions.

Findings

Measured galaxy velocity dispersions at z=0.25 and 0.38.

Results align with LCDM predictions, inconsistent with DGP model.

Lower velocity dispersions compared to low-redshift measurements.

Abstract

We present new measurements of the coherent motion of galaxies based on observations of the large-scale redshift-space distortions seen in the two-dimensional two-point correlation function of Luminous Red Galaxies in Data Release Seven of the Sloan Digital Sky Survey. We have developed a new methodology for estimating these coherent motions, which is less dependent on the details of galaxy bias and of the cosmological model to explain the late-time acceleration of the expansion of the Universe. We measure a one-dimensional velocity dispersion of galaxies on large-scales of \sigma_v=3.01^{+0.45}_{-0.46} Mpc/h and \sigma_v=3.69^{+0.47}_{-0.47} \mpcoh$ at a mean redshift of z=0.25 and 0.38 respectively. These values are fully consistent with predictions for a WMAP7-normalised LCDM Universe and inconsistent at confidence of 3.8\sigma with a Dvali-Gabadadze-Porrati (DGP) model for the Universe. We can convert the units of these $\sigma_v$ measurements to 270^{+40}_{-41} km/s and 320^{+41}_{-41} km/s respectively (assuming a $\Lambda$CDM universe), which are lower that expected based on recent low redshift (z<0.2) measurements of the peculiar velocity field (or "bulk flows"). It is difficult to directly compare these measurements as they cover different redshift ranges and different areas of the sky. However, one possible cosmological explanation for this discrepancy is that our Galaxy is located in unusually over, or under, dense region of the Universe.