Forecasting Dark Matter Subhalo Constraints from Stellar Streams using Implicit Likelihood Inference

TL;DR

This paper demonstrates that neural posterior estimation can accurately constrain dark matter subhalo properties from stellar stream data, even under realistic observational limitations, aiding future survey strategies.

Contribution

It introduces the application of implicit likelihood inference to stellar stream data for dark matter subhalo constraints, highlighting its effectiveness across various observational scenarios.

Findings

NPE yields accurate subhalo mass posteriors with 15-20% uncertainty in ideal conditions.

Realistic observations lead to 20-50% mass uncertainties, depending on data completeness.

Velocity bimodality can be resolved with combined photometric and spectroscopic data.

Abstract

The evidence for dark matter (DM) remains compelling, although attempts to understand its particle nature remain inconclusive. One promising method to study DM is detecting DM subhalos through their gravitational interactions with stellar streams. In this study, we apply Neural Posterior Estimation (NPE) to constrain subhalo interaction parameters, including mass, scale radius, velocity, and encounter geometry, from stellar stream kinematics. We generate particle spray simulations based on the Lagrange Cloud stripping technique, focusing on the ATLAS-Aliqa Uma stream as a test case. We train multiple NPE models across multiple observational scenarios, quantifying how kinematic completeness affects inference and forecasting constraints from upcoming surveys including LSST, 4MOST, and 10-year Gaia data. Our results demonstrate that NPE can produce accurate and well-calibrated posteriors. In the idealized case with full 6D coordinates, we achieve subhalo mass uncertainties of 15-20% for a $10^7 \, \mathrm{M_\odot}$ subhalo, with 5D coordinates (excluding radial velocities) achieving similar performance. Under realistic observational conditions, mass uncertainties range from 50% (present-day) to 20-40% (future scenarios), with comparable performance between the photometric-only LSST sample and a smaller sample that includes Gaia proper motions and 4MOST radial velocities. Most notably, we find that velocity bimodality emerges when phase space is poorly sampled, whether due to missing kinematic information or limited stellar tracers. Combining large photometric samples with targeted spectroscopic follow-up can effectively resolves this degeneracy. These results demonstrate the power of implicit likelihood inference for optimizing stellar stream observational strategies and forecasting DM subhalo constraints from upcoming surveys.