The Major and Minor Galaxy Merger Rates at z < 1.5

TL;DR

This paper calibrates galaxy merger observability timescales using simulations, enabling more accurate merger rate estimates at z < 1.5, revealing strong evolution for major mergers and little for minor mergers.

Contribution

It provides physically-motivated timescales for galaxy merger detection techniques, improving the accuracy of merger rate calculations across different methods.

Findings

Merger rates depend on the selection technique and mass ratio range.

Major merger rate evolves strongly with redshift, approximately as (1+z)^{3.0}.

Minor merger rate is about three times the major rate at z ~ 0.7 and remains relatively constant.

Abstract

Calculating the galaxy merger rate requires both a census of galaxies identified as merger candidates, and a cosmologically-averaged `observability' timescale T_obs(z) for identifying galaxy mergers. While many have counted galaxy mergers using a variety of techniques, T_obs(z) for these techniques have been poorly constrained. We address this problem by calibrating three merger rate estimators with a suite of hydrodynamic merger simulations and three galaxy formation models. We estimate T_obs(z) for (1) close galaxy pairs with a range of projected separations, (2) the morphology indicator G-M20, and (3) the morphology indicator asymmetry A. Then we apply these timescales to the observed merger fractions at z < 1.5 from the recent literature. When our physically-motivated timescales are adopted, the observed galaxy merger rates become largely consistent. The remaining differences between the galaxy merger rates are explained by the differences in the range of mass-ratio measured by different techniques and differing parent galaxy selection. The major merger rate per unit co-moving volume for samples selected with constant number density evolves much more strongly with redshift (~ (1+z)^(+3.0 \pm 1.1)) than samples selected with constant stellar mass or passively evolving luminosity (~ (1+z)^(+0.1 \pm 0.4)). We calculate the minor merger rate (1:4 < M_{sat}/M_{primary} <~ 1:10) by subtracting the major merger rate from close pairs from the `total' merger rate determined by G-M20. The implied minor merger rate is ~3 times the major merger rate at z ~ 0.7, and shows little evolution with redshift.