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Toward a Physical Understanding of Galaxy–Halo Alignment

Kun Xu, Yipeng Jing, Donghai Zhao

2023The Astrophysical Journal12 citationsDOIOpen Access PDF

Abstract

Abstract We investigate the alignment of galaxy and halo orientations using the TNG300-1 hydrodynamical simulation. Our analysis reveals that the distribution of the 2D misalignment angle θ 2D can be well described by a truncated shifted exponential distribution with only one free parameter across different redshifts and galaxy/halo properties. We demonstrate that the galaxy–ellipticity (GI) correlations of galaxies can be reproduced by perturbing halo orientations with the obtained θ 2D distribution, with only a small bias (<3°) possibly arising from unaccounted for couplings between θ 2D and other factors. We find that both the 2D and 3D misalignment angles θ 2D and θ 3D decrease with ex situ stellar mass fraction F acc , halo mass M vir , and stellar mass M * , while increasing with the disk-to-total stellar mass fraction F disk and redshift. These dependences are in good agreement with our recent observational study based on BOSS galaxy samples. Our results suggest that F acc is a key factor in determining galaxy–halo alignment. Grouping galaxies by F acc nearly eliminates the dependence of θ 3D on M vir for all three principle axes, and also reduces the redshift dependence. For θ 2D , we find a more significant redshift dependence than for θ 3D even after controlling F acc , which may be attributed to the evolution of galaxy and halo shapes. Our findings present a valuable model for observational studies and enhance our understanding of galaxy–halo alignment.

Topics & Concepts

AstrophysicsPhysicsHaloGalaxyRedshiftGalaxy formation and evolutionType-cD galaxyDark matter haloStellar massAstronomyGalactic haloStar formationGalaxies: Formation, Evolution, PhenomenaStellar, planetary, and galactic studiesAstronomy and Astrophysical Research
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