Searching for a kinematic signature of the moderately metal-poor stars in the Milky Way bulge using N-body simulations

Abstract

Although there is consensus that metal-rich stars in the Milky Way bulge are formed via secular evolution of the thin disc, the origin of their metal-poor counterparts is still under debate. Two different origins have been invoked for metal-poor stars: they might be classical bulge stars or stars formed via internal evolution of a massive thick disc. We use N-body simulations to calculate the kinematic signature given by the difference in the mean Galactocentric radial velocity ( V GC) between metal-rich stars ([Fe/H] 0) and moderately metal-poor stars (-1.0 [Fe/H] < 0) in two models, one containing a thin disc and a small classical bulge (B/D=0.1), and the other containing a thin disc and a massive centrally concentrated thick disc. We reasonably assume that thin-disk stars in each model may be considered as a proxy of metal-rich stars. Similarly, bulge stars and thick-disc stars may be considered as a proxy of metal-poor stars. We calculate V GC at different latitudes (b=0, -2, -4,-6, -8 and -10) and longitudes (l=0, 5, 10 and 15) and show that the V GC trends predicted by the two models are different. We compare the predicted results with ARGOS data and APOGEE DR13 data and show that moderately metal-poor stars are well reproduced with the co-spatial stellar discs model, which has a massive thick disc. Our results give more evidence against the scenario that most of the metal-poor stars are classical bulge stars. If classical bulge stars exists, most of them probably have metallicities [Fe/H] < -1 dex, and their contribution to the mass of the bulge should be a small percentage of the total bulge mass.