Mapping the Milky Way with LAMOST III: Complicated spatial structure in the outer disc

Abstract

We present complexity of the Galactic outer disc by fitting the stellar volume densities of the red giant branch stars with a two-disc component model. The discs are confirmed to extend to R19\,kpc. The radial density profile of the discs shows two breaks at R11 and 14\,kpc, respectively, which separate the radial profile into three segments with different scale lengths of 2.120.26, 1.180.08, and 2.72\,kpc at R<11, 11≤ R≤14, and R>14\,kpc, respectively. The first break is likely due to the sudden drop in the radial profile of the thin disc, which may be an evidence of the radial migration. Beyond 14\,kpc, the thick disc becomes prominent and the transition from thin to thick disc leads to the second break. This implies that the geometrically defined thick disc is more radially extended than the thin disc. This is also supported by the larger scale length of the thick disc than that of the thin disc. Meanwhile, the scale height of the thicker component increases from 0.637-0.036+0.056 at R=8 to 1.284-0.079+0.086\,kpc at R=19\,kpc, showing an intensive flared disc. Moreover, rich substructures are displayed in the residuals of the stellar density. Among them, the substructures D14+2.0 and O14-1.5 show a north-south asymmetry, which can be essentially explained by southward shifting of the thick disc. However, no significant overdensity is found for the Monoceros ring. Finally, the thick disc shows a ripple-like feature with unclear origin at 9<R<10.5\,kpc.