We use simulated galaxy surveys to study: i) how galaxy membership in redMaPPer clusters maps to the underlying halo population, and ii) the accuracy of a mean dynamical cluster mass, Mσ(λ), derived from stacked pairwise spectroscopy of clusters with richness λ. Using ∼130,000 galaxy pairs patterned after the SDSS redMaPPer cluster sample study of Rozo et al. (2015 RMIV), we show that the pairwise velocity PDF of central--satellite pairs with mi<19 in the simulation matches the form seen in RMIV. Through joint membership matching, we deconstruct the main Gaussian velocity component into its halo contributions, finding that the top-ranked halo contributes ∼60% of the stacked signal. The halo mass scale inferred by applying the virial scaling of Evrard et al. (2008) to the velocity normalization matches, to within a few percent, the log-mean halo mass derived through galaxy membership matching. We apply this approach, along with mis-centering and galaxy velocity bias corrections, to estimate the log-mean matched halo mass at z=0.2 of SDSS redMaPPer clusters. Employing the velocity bias constraints of Guo et al. (2015), we find ⟨ln(M200c)∣λ⟩=ln(M30)+αmln(λ/30) with M30=1.56±0.35×1014M⊙ and αm=1.31±0.06stat±0.13sys. Systematic uncertainty in the velocity bias of satellite galaxies overwhelmingly dominates the error budget.
@article{arxiv.1601.05773,
title = {Galaxy Cluster Mass Estimation from Stacked Spectroscopic Analysis},
author = {Arya Farahi and August E. Evrard and Eduardo Rozo and Eli S. Rykoff and Risa H. Wechsler},
journal= {arXiv preprint arXiv:1601.05773},
year = {2016}
}