Abstract Perturbations from the Large Magellanic Cloud (LMC) of the Milky Way’s stellar and dark matter haloes are well-established. However, studies have generally not considered the high radial anisotropy of the Milky Way’s inner halo caused by the accreted debris of Gaia Sausage-Enceladus (GSE). We run a series of test particle simulations of stellar haloes being perturbed by the LMC, with different halo velocity anisotropies β ∈ 0.5, 0.9. The LMC causes these initially axisymmetric haloes to become approximately triaxial. Their major axes are aligned with its orbital plane and tilted by up to ~14○ with respect to a fixed Galactic disc. These effects become much more dramatic as β increases, causing the halo to fractionate spatially according to anisotropy. This confirms the expectations of an analytical model, which predicts that orbits with eccentricities e ≳ 0.95 should azimuthally align with the tidal field of the LMC. The reshaping of the β = 0.9 halo creates strong overdensities of ~40% at heliocentric distances as close as 15 kpc. These coincide with the well-known Virgo Overdensity (VOD) and Hercules-Aquila Cloud (HAC), which have previously been associated with the GSE. We propose that the HAC and VOD were created by the dynamical alignment of highly eccentric orbits by the LMC, and are not necessarily relics of the GSE merger geometry. We conclude that previous works have significantly underestimated perturbations from the LMC in the inner stellar halo by not considering sufficiently high velocity anisotropy. This effect should be corrected for when constructing equilibrium models of the GSE debris.
Dillamore et al. (Fri,) studied this question.