Orthogonal vertical velocity dispersion distributions produced by bars

Abstract

In barred galaxies, the contours of stellar velocity dispersions (σ) are generally expected to be oval and aligned with the orientation of bars. However, many double-barred (S2B) galaxies exhibit distinct σ peaks on the minor axis of inner bars, which we termed "σ-humps," while two local σ minima are present close to the ends of inner bars, i.e., "σ-hollows." Analysis of numerical simulations shows that σz-humps or hollows should play an important role in generating the observed σ-humps+hollows in low-inclination galaxies. In order to systematically investigate the properties of σz in barred galaxies, we apply the vertical Jeans equation to a group of well-designed three-dimensional bar+disk(+bulge) models. A vertically thin bar can lower σz along the bar and enhance it perpendicular to the bar, thus generating σz-humps+hollows. Such a result suggests that σz-humps+hollows can be generated by the purely dynamical response of stars in the presence of a, sufficiently massive, vertically thin bar, even without an outer bar. Using self-consistent N-body simulations, we verify the existence of vertically thin bars in the nuclear-barred and S2B models which generate prominent σ-humps+hollows. Thus the ubiquitous presence of σ-humps+hollows in S2Bs implies that inner bars are vertically thin. The addition of a bulge makes the σz-humps more ambiguous and thus tends to somewhat hide the σz-humps+hollows. We show that σz may be used as a kinematic diagnostic of stellar components that have different thickness, providing a direct perspective on the morphology and thickness of nearly face-on bars and bulges with integral field unit spectroscopy.