Structure Formation Inside Triaxial Dark Matter Halos: Galactic Disks, Bulges and Bars

TL;DR

This study models the formation and evolution of galactic disks within triaxial dark matter halos, revealing insights into angular momentum transfer, disk morphology, and bar formation through cosmological simulations.

Contribution

It introduces detailed simulations of galaxy formation in live dark matter halos, incorporating feedback and star formation, and analyzes the resulting disk structures and dynamics.

Findings

Angular momentum is conserved and channeled into internal circulation.

Disks form from initial amorphous structures with radial string patterns.

Extensive bar formation and nuclear bars are observed in the models.

Abstract

We investigate the formation and evolution of galactic disks immersed in assembling live DM halos. Disk/halo components have been evolved from the cosmological initial conditions and represent the collapse of an isolated density perturbation. The baryons include gas (which participates in star formation [SF]) and stars. The feedback from the stellar energy release onto the ISM has been implemented. We find that (1) The growing triaxial halo figure tumbling is insignificant and the angular momentum (J) is channeled into the internal circulation; (2) Density response of the disk is out of phase with the DM, thus diluting the inner halo flatness and washing out its prolateness; (3) The total J is neathly conserved, even in models accounting for feedback; (4) The specific J for the DM is nearly constant, while that for baryons is decreasing; (5) Early stage of disk formation resembles the cat's cradle -- a small amorphous disk fueled via radial string patterns; (6) The initially puffed up gas component in the disk thins when the SF rate drops below ~5 Mo/yr; (7) About 40%-60% of the baryons remain outside the SF region; (8) Rotation curves appear to be flat and account for the observed disk/halo contributions; (9) A range of bulge-dominated to bulgeless disks was obtained; Lower density threshold for SF leads to a smaller, thicker disk; Gravitational softening in the gas has a substantial effect on various aspects of galaxy evolution and mimics a number of intrinsic processes within the ISM; (10) The models are characterized by an extensive bar-forming activity; (11) Nuclear bars, dynamically coupled and decoupled form in response to the gas inflow along the primary bars.