An Alternative Origin for Hypervelocity Stars

TL;DR

This paper proposes that hypervelocity stars may originate from tidal debris of disrupted dwarf galaxies near the Milky Way's center, challenging the traditional black hole ejection explanation and suggesting new observational tests.

Contribution

It introduces a novel hypothesis that hypervelocity stars are tidal debris from dwarf galaxy disruptions, supported by numerical simulations and analysis of their spatial and velocity distributions.

Findings

HVS cluster around Leo and share similar travel times

Velocities of HVS are consistent with being bound in a Milky Way halo

Disrupted dwarf galaxies can produce stars exceeding escape velocity in tidal tails

Abstract

Halo stars with unusually high radial velocity ("hypervelocity" stars, or HVS) are thought to be stars unbound to the Milky Way that originate from the gravitational interaction of stellar systems with the supermassive black hole at the Galactic center. We examine the latest HVS compilation and find peculiarities that are unexpected in this black hole-ejection scenario. For example, a large fraction of HVS cluster around the constellation of Leo and share a common travel time of $\sim 100$-200 Myr. Furthermore, their velocities are not really extreme if, as suggested by recent galaxy formation models, the Milky Way is embedded within a $2.5\times 10^{12} h^{-1} M_{\odot}$ dark halo with virial velocity of $\sim 220$ km/s. In this case, the escape velocity at $\sim 50$ kpc would be $\sim 600$ km/s and very few HVS would be truly unbound. We use numerical simulations to show that disrupting dwarf galaxies may contribute halo stars with velocities up to and sometimes exceeding the nominal escape speed of the system. These stars are arranged in a thinly-collimated outgoing ``tidal tail'' stripped from the dwarf during its latest pericentric passage. We speculate that some HVS may therefore be tidal debris from a dwarf recently disrupted near the center of the Galaxy. In this interpretation, the angular clustering of HVS results because from our perspective the tail is seen nearly ``end on'', whereas the common travel time simply reflects the fact that these stars were stripped simultaneously from the dwarf during a single pericentric passage. This proposal is eminently falsifiable, since it makes a number of predictions that are distinct from the black-hole ejection mechanism and that should be testable with improved HVS datasets.