Minor mergers and the size evolution of elliptical galaxies

TL;DR

This study uses high-resolution simulations to show that minor mergers significantly contribute to the size growth and density decrease of elliptical galaxies from high redshift to the present.

Contribution

It demonstrates through simulations that minor mergers are a key mechanism driving the late evolution of elliptical galaxy sizes and densities.

Findings

Effective radius increases from 0.7 to 2.4 kpc from z=3 to z=0.

Effective density decreases by an order of magnitude.

Central velocity dispersion decreases by approximately 20%.

Abstract

Using a high resolution hydrodynamical cosmological simulation of the formation of a massive spheroidal galaxy we show that elliptical galaxies can be very compact and massive at high redshift in agreement with recent observations. Accretion of stripped in-falling stellar material increases the size of the system with time and the central concentration is reduced by dynamical friction of the surviving stellar cores. In a specific case of a spheroidal galaxy with a final stellar mass of $1.5 \times 10^{11} M_{\odot}$ we find that the effective radius $r_e$ increases from $0.7 \pm 0.2 \rm kpc$ at z = 3 to $r_e = 2.4 \pm 0.4 \rm kpc$ at z = 0 with a concomitant decrease in the effective density of an order of magnitude and a decrease of the central velocity dispersion by approximately 20% over this time interval. A simple argument based on the virial theorem shows that during the accretion of weakly bound material (minor mergers) the radius can increase as the square of the mass in contrast to the usual linear rate of increase for major mergers. By undergoing minor mergers compact high redshift spheroids can evolve into present-day systems with sizes and concentrations similar to observed local ellipticals. This indicates that minor mergers may be the main driver for the late evolution of sizes and densities of early-type galaxies.