English

Tilted outer and inner structures in edge-on galaxies?

Astrophysics of Galaxies 2020-07-15 v1

Abstract

Tilted and warped discs inside tilted dark matter haloes are predicted from numerical and semi-analytical studies. In this paper, we use deep imaging to demonstrate the likely existence of tilted outer structures in real galaxies. We consider two SB0 edge-on galaxies, NGC4469 and NGC4452, which exhibit apparent tilted outer discs with respect to the inner structure. In NGC4469, this structure has a boxy shape, inclined by Δ\DeltaPA\approx3^{\circ} with respect to the inner disc, whereas NGC4452 harbours a discy outer structure with Δ\DeltaPA\approx6^{\circ}. In spite of the different shapes, both structures have surface brightness profiles close to exponential and make a large contribution (30\sim30%) to the total galaxy luminosity. In the case of NGC4452, we propose that its tilted disc likely originates from a former fast tidal encounter (probably with IC3381). For NGC4469, a plausible explanation may also be galaxy harassment, which resulted in a tilted or even a tumbling dark matter halo. A less likely possibility is accretion of gas-rich satellites several Gyr ago. New deep observations may potentially reveal more such galaxies with tilted outer structures, especially in clusters. We also consider galaxies, mentioned in the literature, where a central component (a bar or a bulge) is tilted with respect to the stellar disc. According to our numerical simulations, one of the plausible explanations of such observed "tilts" of the bulge/bar is a projection effect due to a not exactly edge-on orientation of the galaxy coupled with a skew angle of the triaxial bulge/bar.

Keywords

Cite

@article{arxiv.2006.14896,
  title  = {Tilted outer and inner structures in edge-on galaxies?},
  author = {Aleksandr V. Mosenkov and Anton A. Smirnov and Olga K. Sil'chenko and R. Michael Rich and Vladimir P. Reshetnikov and John Kormendy},
  journal= {arXiv preprint arXiv:2006.14896},
  year   = {2020}
}

Comments

20 pages, 19 figures, Accepted for publication in MNRAS

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