The Missing Massive Satellites of the Milky Way

Abstract

Recent studies suggest that only three of the twelve brightest satellites of the Milky Way (MW) inhabit dark matter halos with maximum circular velocity, Vmax, exceeding 30km/s. This is in apparent contradiction with the LCDM simulations of the Aquarius Project, which suggest that MW-sized halos should have at least 8 subhalos with Vmax>30km/s. The absence of luminous satellites in such massive subhalos is thus puzzling and may present a challenge to the LCDM paradigm. We note, however, that the number of massive subhalos depends sensitively on the (poorly-known) virial mass of the Milky Way, and that their scarcity makes estimates of their abundance from a small simulation set like Aquarius uncertain. We use the Millennium Simulation series and the invariance of the scaled subhalo velocity function (i.e., the number of subhalos as a function of , the ratio of subhalo Vmax to host halo virial velocity, V200) to secure improved estimates of the abundance of rare massive subsystems. In the range 0.1<<0.5, Nsub(>) is approximately Poisson-distributed about an average given by <Nsub>=10.2x(/0.15)(-3.11). This is slightly lower than in Aquarius halos, but consistent with recent results from the Phoenix Project. The probability that a LCDM halo has 3 or fewer subhalos with Vmax above some threshold value, Vth, is then straightforward to compute. It decreases steeply both with decreasing Vth and with increasing halo mass. For Vth=30km/s, ~40% of Mhalo=1012 Msun halos pass the test; fewer than 5% do so for Mhalo>= 2x1012 Msun; and the probability effectively vanishes for Mhalo>= 3x 1012 Msun. Rather than a failure of LCDM, the absence of massive subhalos might simply indicate that the Milky Way is less massive than is commonly thought.