Cross-correlation Weak Lensing of SDSS Galaxy Clusters III: Mass-to-light Ratios

Abstract

We present measurements of the excess mass-to-light ratio measured aroundMaxBCG galaxy clusters observed in the SDSS. This red sequence cluster sample includes objects from small groups with masses ranging from ~5x1012 to ~1015 Msun/h. Using cross-correlation weak lensing, we measure the excess mass density profile above the universal mean (r) = (r) - for clusters in bins of richness and optical luminosity. We also measure the excess luminosity density l(r) = l(r) - l measured in the z=0.25 i-band. For both mass and light, we de-project the profiles to produce 3D mass and light profiles over scales from 25 kpc/ to 22 Mpc/h. From these profiles we calculate the cumulative excess mass M(r) and excess light L(r) as a function of separation from the BCG. On small scales, where (r) >> , the integrated mass-to-light profile may be interpreted as the cluster mass-to-light ratio. We find the M/L200, the mass-to-light ratio within r200, scales with cluster mass as a power law with index 0.33+/-0.02. On large scales, where (r) ~ , the M/L approaches an asymptotic value independent of cluster richness. For small groups, the mean M/L200 is much smaller than the asymptotic value, while for large clusters it is consistent with the asymptotic value. This asymptotic value should be proportional to the mean mass-to-light ratio of the universe <M/L>. We find <M/L>/b2ml = 362+/-54 h (statistical). There is additional uncertainty in the overall calibration at the ~10% level. The parameter bml is primarily a function of the bias of the L <~ L* galaxies used as light tracers, and should be of order unity. Multiplying by the luminosity density in the same bandpass we find m/b2ml = 0.02+/-0.03, independent of the Hubble parameter.