Inferring the Morphology of Stellar Distribution in TNG50: Twisted and Twisted-stretched Shapes

• Published in: The Astrophysical journal Vol. 918; no. 1; pp. 7 - 30
• Main Authors: Emami, Razieh, Hernquist, Lars, Alcock, Charles, Genel, Shy, Bose, Sownak, Weinberger, Rainer, Vogelsberger, Mark, Shen, Xuejian, Speagle, Joshua S., Marinacci, Federico, Forbes, John C., Torrey, Paul
• Format: Journal Article
• Language: English
• Published: Philadelphia The American Astronomical Society 01.09.2021; IOP Publishing
• Subjects: Angular momentum; Astrophysics; Circularity; Dark matter; Eigenvectors; Galactic halos; Galaxies; Galaxy classification systems; Galaxy distribution; Halos; Hydrodynamical simulations; Milky Way; Milky Way stellar halo; Morphology; Parameters; Stars; Tensors
• ISSN: 0004-637X; 1538-4357
• DOI: 10.3847/1538-4357/ac088b

Abstract We investigate the morphology of the stellar distribution (SD) in a sample of Milky Way–like galaxies in the TNG50 simulation. Using a local in shell iterative method as the main approach, we explicitly show evidence of twisting (in about 52% of halos) and stretching (in 48% of them) in real space. This is matched with the reorientation observed in the eigenvectors of the inertia tensor and gives us a clear picture of having a reoriented SD. We make a comparison between the shape profile of the dark matter (DM) halo and SD and quite remarkably see that their radial profiles are fairly close, especially at small galactocentric radii, where the stellar disk is located. This implies that the DM halo is somewhat aligned with stars in response to the baryonic potential. The level of alignment mostly decreases away from the center. We study the impact of substructures in the orbital circularity parameter. It is demonstrated that in some cases, faraway substructures are counterrotating compared with the central stars and may flip the sign of total angular momentum and thus the orbital circularity parameter. Truncating them above 150 kpc, however, retains the disky structure of the galaxy as per initial selection. Including the impact of substructures in the shape of stars, we explicitly show that their contribution is subdominant. Overlaying our theoretical results on the observational constraints from previous literature, we establish fair agreement.