Abstract

We explore models of massive (>10(10)M(circle dot)) satellite quenching in massive clusters at z greater than or similar to 1 using an MCMC framework, focusing on two primary parameters: R-quench (the host-centric radius at which quenching begins) and tau (quench) (the time-scale upon which a satellite quenches after crossing R-quench). Our MCMC analysis shows two local maxima in the 1D posterior probability distribution of R-quench at approximately 0.25 and 1.0R(200). Analysing four distinct solutions in the tau (quench)-R-quench parameter space, nearly all of which yield quiescent fractions consistent with observational data from the GOGREEN survey, we investigate whether these solutions represent distinct quenching pathways and find that they can be separated between 'starvation' and 'core quenching' scenarios. The starvation pathway is characterized by quenching time-scales that are roughly consistent with the total cold gas (H-2 + Hi) depletion time-scale at intermediate z, while core quenching is characterized by satellites with relatively high line-of-sight velocities that quench on short time-scales (similar to 0.25Gyr) after reaching the inner region of the cluster (<0.30R(200)). Lastly, we break the degeneracy between these solutions by comparing the observed properties of transition galaxies from the GOGREEN survey. We conclude that only the 'starvation' pathway is consistent with the projected phase-space distribution and relative abundance of transition galaxies at z 1. However, we acknowledge that ram pressure might contribute as a secondary quenching mechanism.