The Smith Cloud: high-velocity accretion and dark-matter confinement

TL;DR

This study investigates the orbit and dark matter confinement of the Smith Cloud, a high-velocity gas cloud, suggesting it is likely dark matter dominated and has undergone recent disk transit, with implications for its survival.

Contribution

It introduces models of the Smith Cloud confined by different dark matter halos, analyzing their effects on the cloud's orbit and survival during Galactic interactions.

Findings

Dark matter halos can explain the cloud's current orbit and survival.

The progenitor had significantly more mass than observed today.

The cloud likely transited the Galactic disk about 70 million years ago.

Abstract

The Smith Cloud is a massive system of metal-poor neutral and ionized gas M_gas >= 2x10^6 M_sun) that is presently moving at high velocity (V_GSR ~300 km s^-1) with respect to the Galaxy at a distance of 12 kpc from the Sun. The kinematics of the cloud's cometary tail indicates that the gas is in the process of accretion onto the Galaxy, as first discussed by Lockman et al. (2008). Here, we re-investigate the cloud's orbit by considering the possibility that the cloud is confined by a dark matter halo. This is required for the cloud to survive its passage through the Galactic corona. We consider three possible models for the dark matter halo (NFW, Einasto, Burkert) including the effects of tidal disruption and ram-pressure stripping during the cloud's infall onto and passage through the Galactic disk. For the NFW and Einasto dark-matter models, we are able to determine reasonable initial conditions for the Smith Cloud, although this is only marginally possible with the Burkert model. For all three models, the progenitor had an initial (gas+dark matter) mass that was an order of magnitude higher than inferred today. In agreement with Lockman et al. (2008), the cloud appears to have punched through the disk ~70 Myr ago. For our most successful models, the baryon to dark matter ratio is fairly constant during an orbital period but drops by a factor of 2-5 after transiting the disk. The cloud appears to have only marginally survived its transit, and is unlikely to retain its integrity during the next transit ~30 Myr from now.