On the Effect of the Large Magellanic Cloud on the Orbital Poles of Milky Way Satellite Galaxies

The reflex motion and distortion of the Milky Way (MW) halo caused by the infall of a massive Large Magellanic Cloud (LMC) was shown to result in an excess of orbital poles of dark matter halo particles towards the LMC orbital pole. This was suggested to help explain the observed preference of MW satellite galaxies to co-orbit along the Vast Polar Structure (VPOS), the MW's satellite plane. We test this idea by correcting the positions and velocities of the MW satellites for the Galactocentric-distance-dependent shifts inferred from a LMC-infall simulation. While this should substantially reduce the observed clustering of orbital poles if it were mainly caused by the LMC, we instead find that the strong clustering remains preserved. We confirm the initial study's result with our own simulation of an MW-LMC-like interaction, and use it to identify two reasons why this scenario is unable to explain the VPOS: (1) the orbital pole enhancement is very mild ($\sim10\%$) compared to the substantial observed enhancement ($\sim300\%$), and (2) it is very sensitive to the specific angular momenta of the simulation particles, with higher angular momentum particles being affected the least. Particles in simulated dark matter halos tend to follow more radial orbits (lower angular momentum), so their orbital poles are more easily affected by small offsets in position and velocity caused by an LMC infall than objects with more tangential velocity (higher angular momentum), such as the observed dwarf galaxies surrounding the MW. The origin of the VPOS thus remains unexplained.