Stellar velocity dispersion and initial mass function gradients in dissipationless galaxy mergers

TL;DR

This study investigates how dissipationless galaxy mergers influence the distribution of the initial mass function (IMF) gradients in early-type galaxies, revealing that mergers tend to flatten IMF profiles and affect galaxy velocity dispersion and IMF mismatch parameters.

Contribution

It provides new insights into the impact of dry mergers on IMF gradients and the evolution of galaxy properties, using simulation results to model these effects.

Findings

Dry mergers flatten IMF mismatch parameter profiles.

Mergers can decrease the effective IMF mismatch parameter $\alpha_{e}$.

Galaxy velocity dispersion $\sigma_{e}$ can increase or decrease depending on merger parameters.

Abstract

The stellar initial mass function (IMF) is believed to be non-universal among early-type galaxies (ETGs). Parameterizing the IMF with the so-called IMF mismatch parameter $\alpha_{\rm IMF}$, which is a measure of the stellar mass-to-light ratio of an ensemble of stars and thus of the 'heaviness' of its IMF, one finds that for ETGs $\alpha_{\rm e}$ (i.e. $\alpha_{\rm IMF}$ integrated within the effective radius $R_{\rm e}$) increases with $\sigma_{\rm e}$ (the line-of-sight velocity dispersion $\sigma_{\rm los}$ integrated within $R_{\rm e}$) and that, within the same ETG, $\alpha_{\rm IMF}$ tends to decrease outwards. We study the effect of dissipationless (dry) mergers on the distribution of the IMF mismatch parameter $\alpha_{\rm IMF}$ in ETGs using the results of binary major and minor merging simulations. We find that dry mergers tend to make the $\alpha_{\rm IMF}$ profiles of ETGs shallower, but do not alter significantly the shape of the distributions in the spatially resolved $\sigma_{\rm los}\alpha_{\rm IMF}$ space. Individual galaxies undergoing dry mergers tend to decrease their $\alpha_{\rm e}$, due to erosion of $\alpha_{\rm IMF}$ gradients and mixing with stellar populations with lighter IMF. Their $\sigma_{\rm e}$ can either decrease or increase, depending on the merging orbital parameters and mass ratio, but tends to decrease for cosmologically motivated merging histories. The $\alpha_{\rm e}$-$\sigma_{\rm e}$ relation can vary with redshift as a consequence of the evolution of individual ETGs: based on a simple dry-merging model, ETGs of given $\sigma_{\rm e}$ are expected to have higher $\alpha_{\rm e}$ at higher redshift, unless the accreted satellites are so diffuse that they contribute negligibly to the inner stellar distribution of the merger remnant.