The Structures of Distant Galaxies I: Galaxy Structures and the Merger Rate to z~3 in the Hubble Ultra-Deep Field

TL;DR

This study analyzes the structures of distant galaxies in the Hubble Ultra-Deep Field to understand their formation history, morphological classifications, and merger rates up to redshift 3, revealing rapid galaxy assembly and merger activity.

Contribution

It provides a comprehensive comparison of visual and quantitative galaxy classification methods and estimates galaxy merger rates up to z~3, highlighting the evolution of galaxy structures over cosmic time.

Findings

Most galaxies with z_850 < 27 are peculiar, indicating active assembly.

Quantitative methods largely agree with visual classifications.

Merger rate increases with redshift and stellar mass, with massive galaxies undergoing multiple mergers.

Abstract

This paper begins a series in which we examine the structures of distant galaxies to directly determine the history of their formation modes. We start this series by examining the structures of z_F850LP < 27 galaxies in the Hubble Ultra-Deep field, the deepest high-resolution optical image taken to date. We investigate a few basic features of galaxy structure using this image. These include: (1) The agreement of visual eye-ball classifications and non-parametric quantitative (CAS, Gini/M_20) methods; (2) How distant galaxy quantitative structures can vary as a function of rest-frame wavelength; and (3) The evolution of distant galaxy structures up to z~3. One of our major conclusions is that the majority of galaxies with z_850 < 27 are peculiar in appearance, and that galaxy assembly is rapidly occurring at these magnitudes, even up to the present time. We find a general agreement between galaxy classification by eye and through quantitative methods, as well as a general agreement between the CAS and the Gini/M_20 parameters. We find that the Gini/M_20 method appears to find a larger number of galaxy mergers than the CAS system, but contains a larger contamination from non-mergers. We furthermore calculate the merger rate of galaxies in the UDF up to z~3, finding an increase with redshift as well as stellar mass, confirming previous work in the Hubble Deep Field. We find that massive galaxies with M_{*} > 10^10 M_0 undergo 4.3_+0.8^-0.8 major galaxy mergers at z < 3, with all of this merging occurring at z > 1.