# The local high velocity tail and the Galactic escape speed

**Authors:** Alis J. Deason (Durham), Azadeh Fattahi (Durham), Vasily Belokurov, (Cambridge), Wyn Evans (Cambridge), Robert J. Grand (MPA), Federico Marinacci, (Harvard), Rudiger Pakmor (MPA)

arXiv: 1901.02016 · 2019-03-13

## TL;DR

This study combines cosmological simulations and Gaia data to model the high velocity tail of halo stars, constraining the Milky Way's escape speed and total mass with improved accuracy.

## Contribution

It introduces a novel method using simulations and phase-space knowledge to better estimate the Galactic escape speed and mass from high velocity stars.

## Key findings

- Measured local escape speed as 528 km/s with uncertainties.
- Estimated Milky Way mass as approximately 1 x 10^12 solar masses.
- Confirmed consistency with recent Milky Way mass estimates.

## Abstract

We model the fastest moving (v_tot > 300 km/s) local (D < 3 kpc) halo stars using cosmological simulations and 6-dimensional Gaia data. Our approach is to use our knowledge of the assembly history and phase-space distribution of halo stars to constrain the form of the high velocity tail of the stellar halo. Using simple analytical models and cosmological simulations, we find that the shape of the high velocity tail is strongly dependent on the velocity anisotropy and number density profile of the halo stars --- highly eccentric orbits and/or shallow density profiles have more extended high velocity tails. The halo stars in the solar vicinity are known to have a strongly radial velocity anisotropy, and it has recently been shown the origin of these highly eccentric orbits is the early accretion of a massive (M_star ~ 10^9 M_Sun) dwarf satellite. We use this knowledge to construct a prior on the shape of the high velocity tail. Moreover, we use the simulations to define an appropriate outer boundary of 2r_200, beyond which stars can escape. After applying our methodology to the Gaia data, we find a local (r_0=8.3 kpc) escape speed of v_esc(r_0) = 528(+24,-25) km/s. We use our measurement of the escape velocity to estimate the total Milky Way mass, and dark halo concentration: M_200,tot = 1.00(+0.31,-0.24) x 10^12 M_Sun, c_200 = 10.9(+4.4,-3.3). Our estimated mass agrees with recent results in the literature that seem to be converging on a Milky Way mass of M_200,tot ~ 10^12 M_Sun.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1901.02016/full.md

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1901.02016/full.md

## References

92 references — full list in the complete paper: https://tomesphere.com/paper/1901.02016/full.md

---
Source: https://tomesphere.com/paper/1901.02016