The Structures of Distant Galaxies - IV: A New Empirical Measurement of the Time-Scale for Galaxy Mergers - Implications for the Merger History

TL;DR

This paper empirically measures the duration galaxies remain identifiable as merging systems using the CAS system, providing key insights into galaxy merger rates and history at redshifts below 1.2.

Contribution

It introduces the first observationally based measurement of galaxy merger time-scales, aligning empirical data with theoretical models and refining merger rate estimates.

Findings

Maximum merger time-scale of 1.1 Gyr at z<1.2

Most likely merger time-scale of 0.6 Gyr

Average galaxy undergoes approximately 0.9 major mergers since z<1.2

Abstract

Understanding the role of mergers in galaxy formation is one of the most outstanding problems in extragalactic astronomy. While we now have an idea for how the merger fraction evolves at redshifts z < 3, converting this merger fraction into merger rates, and therefore how many mergers an average galaxy undergoes during its history, is still uncertain. The main reason for this is that the inferred number of mergers depends highly upon the time-scale observational methods are sensitive for finding ongoing or past mergers. While there are several theoretical and model-based estimates of merger times, there is currently no empirical measure of this time-scale. We present the first observationally based measurement of merger times utilising the observed decline in the galaxy major merger fraction at z < 1.2 based on > 20,000 galaxies in the Extended Groth Strip and COSMOS surveys. Using a new methodology described in this paper, we determine how long a galaxy remains identifiable as a merging system within the CAS system. We find a maximum CAS major merger time-scale of 1.1+/-0.3 Gyr at z < 1.2, and a most likely CAS merger time-scale of 0.6+/-0.3 Gyr, in good agreement with results from N-body simulations. Utilizing this time-scale we measure the number of major mergers galaxies with masses M_{*} > 10^{10} M_0 undergo at z < 1.2, with a total number N_m = 0.90_{-0.23}^{+0.44}. We further show that this time-scale is inconsistent with a star formation origin for ultra-high asymmetries, thereby providing further evidence that structural methods are able to locate mostly merging galaxies.