A New Probe of the Distribution of Dark Matter in Galaxies

TL;DR

This paper introduces a novel observational method using disturbances in galaxy gas disks to measure the dark matter halo scale radius, providing a new tool for understanding galaxy mass distribution.

Contribution

The paper presents a new, observationally motivated probe based on gas disk disturbances to infer dark matter halo scale radii, complementing existing methods like gravitational lensing.

Findings

Disturbances in gas disks can reveal dark matter halo properties.

The method applied to the Whirlpool Galaxy yields consistent results.

Results are robust against orbital inclination and initial condition variations.

Abstract

The scale radius of dark matter halos is a critical parameter for specifying the density distribution of dark matter, and is therefore a fundamental parameter for modeling galaxies. We develop here a novel, observationally motivated probe to quantitatively infer its value. We demonstrate that disturbances in the extended atomic hydrogen gas disks of galaxies can be used to infer the scale radius of dark matter halos. Our primary metric is the phase of the $m=1$ mode of the disturbance in the outskirts of the gas disk, which we take to be produced by a tidal interaction. We apply the method to the Whirlpool Galaxy, which has an optically visible satellite. We explore potential degeneracies due to orbital inclination and initial conditions and find our results to be relatively insensitive to these considerations. Our method of tracing the dark potential well through observed disturbances in outer gas disks is complementary to gravitational lensing.