Mass density structuring around galaxy formation sites: impact on galaxy basic properties

TL;DR

This study investigates how the local mass density and shape evolution around galaxy formation sites influence galaxy properties, using the EAGLE simulation to track anisotropic mass flows and shape changes from high redshift to the present.

Contribution

It introduces a novel analysis of the anisotropic evolution of Lagrangian volumes around galaxy sites, linking shape parameters and mass flows to galaxy mass and rotation properties.

Findings

Prolate LVs tend to host low-mass galaxies at z=0.

Massive galaxies form in triaxial or oblate LVs.

Anisotropic mass rearrangements cease around 10.5 Gyr after the Big Bang.

Abstract

We study the local evolution of the Universe around galaxy formation sites in the EAGLE50 large-volume reference simulation. Using the reduced inertia tensor (r-TOI), we followed the anisotropic evolution of initially spherical Lagrangian volumes (LVs) centred at galaxy formation sites, both in dark matter (DM) and in cold baryons (CB), from very high redshift $z=15$ onward. We describe LV deformation in terms of the r-TOI eigen-directions, principal axes, their derived shape parameters, and the timescales for the freezing-out of these principal directions and axes. Of particular interest are the age of the Universe, $t_{\rm U}$, when the local Cosmic Web (CW) spine emerges, and that when anisotropic DM mass arrangements (i.e., migrant mass flows) cease. We find that the shapes LVs acquire along their evolution affect the halo and stellar mass of their central galaxy: prolate-shaped LVs show a tendency to host low-mass galaxies at $z=0$, while massive galaxies tend to form within triaxial or oblate LVs. Also, the local CW spine tends to set in earlier on in LVs that are to host massive galaxies than in those harbouring less massive galaxies. In addition, anisotropic DM-mass rearrangements stop late on average, at $t_{\rm U}\sim 10.5\,$Gyr, and even slightly later for CB. Interestingly, $z=0$ LVs with either flattened configurations in CB or those that are highly prolate in DM, are more likely to host rotation-dominated galaxies. This effect increases from $z=1$ to $z=0$. Finally, the CB spine of LVs that are more likely to host rotation-dominated galaxies emerges at later times.