Abstract
We employ numerical simulations and simple analytical estimates to argue that dark matter substructures orbiting in the inner regions of the Galaxy can be efficiently destroyed by disk shocking, a dynamical process known to affect globular star clusters. We carry out a set of fiducial high-resolution collisionless simulations in which we adiabatically grow a disk, allowing us to examine the impact of the disk on the substructure abundance. We also track the orbits of dark matter satellites in the high-resolution Aquarius simulations and analytically estimate the cumulative halo and disk shocking effect. Our calculations indicate that the presence of a disk with only 10% of the total Milky Way mass can significantly alter the mass function of substructures in the inner parts of halos. This has important implications especially for the relatively small number of satellites seen within ~30 kpc of the Milky Way center, where disk shocking is expected to reduce the substructure abundance by a factor of ~2 at 10^9 M$_{\odot}$ and ~3 at 10^7 M$_{\odot}$. The most massive subhalos with 10^10 M$_{\odot}$ survive even in the presence of the disk. This suggests that there is no inner missing satellite problem, and calls into question whether these substructures can produce transient features in disks, like multi-armed spiral patterns. Also, the depletion of dark matter substructures through shocking on the baryonic structures of the disk and central bulge may aggravate the problem to fully account for the observed flux anomalies in gravitational lens systems, and significantly reduces the dark matter annihilation signal expected from nearby substructures in the inner halo.
Highlights
In the cold dark matter (CDM) scenario, structure grows hierarchically, with small objects collapsing first and continuously merging to form larger and larger bodies (White & Rees 1978)
We employ numerical simulations and simple analytical estimates to argue that dark matter substructures orbiting in the inner regions of the Galaxy can be efficiently destroyed by disk shocking, a dynamical process known to affect globular star clusters
Tidal halo shocking and disk shocking are dominant effects compared to tidal stripping for fairly eccentric orbits and have not been included in all previous simulations of dark satellites orbiting luminous galaxies like the Milky Way
Summary
In the cold dark matter (CDM) scenario, structure grows hierarchically, with small objects collapsing first and continuously merging to form larger and larger bodies (White & Rees 1978). Because the subhalos hosting the satellite galaxies formed early, when the Universe was dense, the smaller structures are thought to be resilient to tidal disruption and the simulations predict that ∼ 100 with maximum circular velocity larger than 20 km s−1 should survive to the present day for a halo like that of the Milky Way (Klypin et al 1999; Moore et al 1999; Diemand et al 2008; Springel et al 2008b; Kravtsov 2009) These estimates of substructure abundance at different locations within a halo, from the solar neighborhood to the outskirts of the Milky Way, are based on simulations that include only dark matter and do not account for ordinary baryonic material (but see Dolag et al 2008). A precise understanding of the impact of baryons on the substructure abundance is important to correctly assess the relevance of substructures for the evolution of galaxies, and for attempts
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