Evidence for Cold-stream to Hot-accretion Transition as Traced by Ly alpha Emission from Groups and Clusters at 2 < z < 3.3

Abstract

We present Keck Cosmic Web Imager observations of giant Ly alpha halos surrounding nine galaxy groups and clusters at 2 < z < 3.3, including five new detections and one upper limit. We find observational evidence for the cold-stream to hot-accretion transition predicted by theory by measuring a decrease in the ratio between the spatially extended Ly alpha luminosity and the expected baryonic accretion rate (BAR), with increasing elongation above the transition mass (M-stream). This implies a modulation of the share of BAR that remains cold, diminishing quasi-linearly (logarithmic slope of 0.97 +/- 0.19, 5 sigma significance) with the halo to M-stream mass ratio. The integrated star formation rates (SFRs) and active galactic nucleus (AGN) bolometric luminosities display a potentially consistent decrease, albeit significant only at 2.6 sigma and 1.3 sigma, respectively. The higher scatter in these tracers suggests the Ly alpha emission might be mostly a direct product of cold accretion in these structures rather than indirect, mediated by outflows and photoionization from SFR and AGNs; this is also supported by energetics considerations. Below M-stream (cold-stream regime), we measure L (Ly alpha) /BAR = 10(40.51 +/- 0.16) erg s(-1) M-circle dot(-1) yr, consistent with predictions, and SFR/BAR = 10(-0.54 +/- 0.23): on average, 30(-10)(+20) M-stream (hot-accretion regime), L-Ly alpha is set by M-stream (within 0.2 dex scatter in our sample), independent of the halo mass but rising 10-fold from z = 2 to 3.