Abstract
The dark matter subhalo mass function is a promising way of distinguishing between dark matter models. While cold dark matter predicts halos down to Earth-sized masses, other dark matter models typically predict a cut-off in the subhalo mass function. Thus a definitive detection or limits on the existence of subhalos at small masses can give us insight into the nature of dark matter. If these subhalos exist in the Milky Way, they would produce weak lensing signatures, such as modified apparent positions, on background stars. These signatures would generate correlations in the apparent velocities and accelerations of these stars, which could be observable given sufficient astrometric resolution and cadence. The Nancy Grace Roman Space Telescope's Exoplanet Microlensing Survey will be perfectly suited to measuring the acceleration signatures of these halos. Here we forward model these acceleration signatures and explore the Roman Space Telescope's future constraints on lens profiles and populations. We find that the Roman Space Telescope could place competitive bounds on point source, Gaussian, and Navarro-Frenk-White (NFW) profile lenses that are complementary to other proposed methods. In particular, it could place 95% upper limits on the NFW concentration, $c_{200} < 10^{2.5}$. We discuss possible systematic effects that could hinder these efforts, but argue they should not prevent the Roman Space Telescope from placing strong limits. We also discuss further analysis methods for improving these constraints.
Highlights
We have known about dark matter (DM) for many decades [1,2,3], we have yet to find a particle responsible for its effects
While we have observed many DM signatures, one feature is both universal to all galaxies and discerning of different particle models: the subhalo mass function, which describes the distribution of subgalactic DM halos within galaxies
The point-source case is most relevant for massive compact halo objects (MACHOs); as we describe in Sec
Summary
We have known about dark matter (DM) for many decades [1,2,3], we have yet to find a particle responsible for its effects. While we have observed many DM signatures, one feature is both universal to all galaxies and discerning of different particle models: the subhalo mass function, which describes the distribution of subgalactic DM halos within galaxies. [27] explored the weak lensing signatures that DM subhalos would induce on stars within the Milky Way. More recently, Ref. [27] explored the weak lensing signatures that DM subhalos would induce on stars within the Milky Way These vary depending on the types of halos (e.g., point-source or diffuse). We forward model the constraints that the Nancy Grace Roman Space Telescope’s EML survey would place on DM subhalos in the Milky Way. In Sec. II we summarize the lensing signature we expect. IV we present our results, discuss possible systematics, and identify avenues for improved constraints
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