Revealing impacts of stellar mass and environment on galaxy quenching

TL;DR

This study investigates how stellar mass and environment influence galaxy quenching at redshifts 0.5 to 1.0, revealing that quenching efficiency increases with mass and density, and different quenching timescales dominate based on galaxy properties.

Contribution

It introduces a statistical method to classify and analyze galaxy quenching stages using UVJ diagrams and spectroscopic validation, applicable to future surveys.

Findings

Quenching efficiency increases with stellar mass and environmental density.

Massive and dense environment galaxies quench earlier.

Slow quenching dominates for massive galaxies at lower redshifts.

Abstract

Galaxy quenching is a critical step in galaxy evolution. In this work, we present a statistical study of galaxy quenching in 17 cluster candidates at 0.5<z<1.0 in the COSMOS field. We selected cluster members with a wide range of stellar mass and environment to study their mass and environment dependence. Member galaxies are classified into star-forming, quiescent and recently-quenched galaxies (RQG) using the rest-frame UVJ diagram. We further separated fast and slow quenching RQGs by model evolutionary tracks on the UVJ diagram. We defined the quenching efficiency as the ratio of RQGs over star-forming galaxies and the quenching stage as the ratio of RQGs over quiescent galaxies to quantify the quenching processes. We found quenching efficiency is enhanced by both higher stellar mass and denser environment. Massive or dense environment galaxies quench earlier. Slow quenching is more dominant for massive galaxies and at lower redshifts, but no clear dependence on the environment is found. Our results suggest that low-mass galaxies in dense environments are likely quenched through a short-timescale process such as ram pressure stripping, while massive galaxies in a sparse environment are mostly quenched by a longer-timescale process. Using the line strength of H$\delta$ and [OII], we confirmed that our UVJ method to select RQGs agrees with high S/N DEIMOS spectra. However, we caution that the visibility time (duration of a galaxy's stay in the RQG region on the UVJ diagram) may also depend on mass or environment. The method introduced in this work can be applied to RQG candidates for future statistical RQG spectroscopic surveys. The systematic spectroscopic RQG study will disentangle the degeneracy between visibility time and quenching properties.