The quiescent phase of galactic disc growth

TL;DR

This study uses N-body simulations to explore the quiescent phase of galactic disc growth, focusing on the effects of spiral structure, GMC heating, and other factors on disc morphology and evolution.

Contribution

It introduces a comprehensive simulation framework including GMCs and gas components, revealing their roles in disc heating, bar formation delay, and vertical structure development.

Findings

GMC heating produces exponential vertical profiles matching observations.

GMCs delay bar formation significantly.

Radial migration aligns with observed metallicity distributions.

Abstract

We perform a series of controlled N-body simulations of growing disc galaxies within non-growing, live dark matter haloes of varying mass and concentration. Our initial conditions include either a low-mass disc or a compact bulge. New stellar particles are continuously added on near-circular orbits to the existing disc, so spiral structure is continuously excited. To study the effect of combined spiral and giant molecular cloud (GMC) heating on the discs we introduce massive, short-lived particles that sample a GMC mass function. An isothermal gas component is introduced for a subset of the models. We perform a resolution study and vary parameters governing the GMC population, the histories of star formation and radial scale growth. Models with GMCs and standard values for the disc mass and halo density provide the right level of self-gravity to explain the age velocity dispersion relation of the Solar neighbourhood (Snhd). GMC heating generates remarkably exponential vertical profiles with scaleheights that are radially constant and agree with observations of galactic thin discs. GMCs are also capable of significantly delaying bar formation. The amount of spiral induced radial migration agrees with what is required for the metallicity distribution of the Snhd. However, in our standard models the outward migrating populations are not hot enough vertically to create thick discs. Thick discs can form in models with high baryon fractions, but the corresponding bars are too long, the young stellar populations too hot and the discs flare considerably.