The Metallicity of Diffuse Intrahalo Light

TL;DR

This paper predicts the metallicity of diffuse stellar components in various galaxy systems by extending existing models and combining them with observed galaxy relations, revealing a strong dependence on host system mass.

Contribution

It introduces a new model for intrahalo light metallicity that accounts for galaxy disruption and observed mass-metallicity relations across a wide range of host masses.

Findings

Metallicity of intrahalo light increases with host mass.

Predicted metallicity ranges from < -2.5 to 0.1 across host masses.

Metallicity distribution narrows as host mass increases.

Abstract

We make predictions for the metallicity of diffuse stellar components in systems ranging from small spiral galaxies to rich galaxy clusters. We extend the formalism of Purcell et al. (2007), in which diffuse stellar mass is produced via galaxy disruption, and we convolve this result with the observed mass-metallicity relation for galaxies in order to analyze the chemical abundance of intrahalo light (IHL) in host halos with virial mass 10^10.5 M_sun < M_host < 10^15 M_sun. We predict a steep rise of roughly two dex in IHL metallicity from the scales of small to large spiral galaxies. In terms of the total dynamical mass M_host of the host systems under consideration, we predict diffuse light metallicities ranging from Z_IHL < -2.5 for M_host ~ 10^11 M_sun, to Z_IHL ~ -1.0 for M_host ~ 10^12 M_sun. In larger systems, we predict a gradual flattening of this trend with Z_IHL ~ -0.4 for M_host ~ 10^13 M_sun, increasing to Z_IHL ~ 0.1 for M_host ~ 10^15 M_sun. This behavior is coincident with a narrowing of the intrahalo metallicity distribution as host mass increases. The observable distinction in surface brightness between old, metal-poor IHL stars and more metal-rich, dynamically-younger tidal streams is of crucial importance when estimating the chemical abundance of an intrahalo population with multiple origins.