The Effects of the Ionizing Radiation Background on Galaxy Evolution

TL;DR

This study investigates how different models of the ionizing radiation background influence galaxy formation and evolution, revealing significant effects on star formation timing, galaxy structure, and substructure reduction.

Contribution

It introduces simulations with alternative UV backgrounds that decline more slowly at high redshift, providing new insights into their impact on galaxy evolution.

Findings

Star formation shifts to lower redshifts with increased ionizing radiation.

Galaxy sizes decrease and velocity dispersions increase under stronger backgrounds.

Substructure in galaxies is significantly reduced.

Abstract

We find that the amount and nature of the assumed ionizing background can strongly affect galaxy formation and evolution. Galaxy evolution simulations typically incorporate an ultraviolet background which falls off rapidly above z=3; e.g., that of Haardt & Madau (1996). However, this decline may be too steep to fit the WMAP constraints on electron scattering optical depth or observations of intermediate redshift (z ~ 2-4) Ly-alpha forest transmission. As an alternative, we present simulations of the cosmological formation of individual galaxies with UV backgrounds that decline more slowly at high redshift: both a simple intensity rescaling and the background recently derived by Faucher-Giguere (2009), which softens the spectrum at higher redshifts. We also test an approximation of the X-ray background with a similar z-dependence. We find for the test galaxies that an increase in either the intensity or hardness of ionizing radiation generically pushes star formation towards lower redshifts: although overall star formation in the simulation boxes is reduced by 10-25%, the galaxies show a factor of ~2 increase in the fraction of stars within a 30 kpc radius that are formed after z=1. Other effects include late gas inflows enhanced up to 30 times, stellar half-mass radii decreased by up to 30%, central velocity dispersions increased up to 40%, and a strong reduction in substructure. The magnitude of the effects depends on the environmental/accretion properties of the particular galaxy.