Box/peanut-shaped bulges in action space

TL;DR

This paper investigates the distribution of stellar populations in action space during bar formation and B/P bulge development, revealing how actions relate to observed metallicity gradients and bulge structure.

Contribution

It introduces a novel analysis of B/P bulges in action space and demonstrates how multiple actions can be used to assign realistic metallicity distributions in N-body galaxy models.

Findings

Low radial and vertical actions trace the B/P X-shape better.

Bar formation alters vertical and radial action profiles.

Using all three actions yields realistic metallicity distributions.

Abstract

We introduce the study of box/peanut (B/P) bulges in the action space of the initial axisymmetric system. We explore where populations with different actions end up once a bar forms and a B/P bulge develops. We find that the density bimodality due to the B/P bulge (the X-shape) is better traced by populations with low radial, JR,0, or vertical, Jz,0, actions, or high azimuthal action, J{\phi},0. Generally populations separated by JR,0 have a greater variation in bar strength and vertical heating than those separated by Jz,0. While the bar substantially weakens the initial vertical gradient of Jz,0, it also drives a strikingly monotonic vertical profile of JR,0. We then use these results to guide us in assigning metallicity to star particles in a pure N-body model. Because stellar metallicity in unbarred galaxies depends on age as well as radial and vertical positions, the initial actions are particularly well suited for assigning metallicities. We argue that assigning metallicities based on single actions, or on positions, results in metallicity distributions inconsistent with those observed in real galaxies. We therefore use all three actions to assign metallicity to an N-body model by comparing with the actions of a star-forming, unbarred simulation. The resulting metallicity distribution is pinched on the vertical axis, has a realistic vertical gradient and has a stronger X-shape in metal-rich populations, as found in real galaxies.