Exploring substructures in the Milky Way halo Neural networks applied to Gaia and APOGEE DR 17

TL;DR

This paper introduces CREEK, a neural network-based clustering method combining chemistry and dynamics to identify stellar structures in the Milky Way halo, successfully recovering known streams and discovering new ones.

Contribution

The paper presents a novel integrated neural network approach, CREEK, that combines multiple models to detect and analyze stellar structures in the Galactic halo using Gaia and APOGEE data.

Findings

Recovered 80% of globular clusters in APOGEE dataset

Re-identified known stellar streams

Discovered a potential new stellar stream

Abstract

The identification of stellar structures in the Galactic halo, including stellar streams and merger remnants, often relies on the dynamics of their constituent stars. However, this approach has limitations due to the complex dynamical interactions between these structures and their environment. Perturbations such as tidal forces exerted by the Milky Way, the potential escape of stars, and passages through the Galactic plane can result in the loss of dynamical coherence of stars in these structures. Consequently, relying solely on dynamics may be insufficient for detecting such disrupted or dispersed remnants. We combine chemistry and dynamics, integrated through a system of neural networks, to develop a clustering method for identifying accreted structures in the Galactic halo. We developed an integrated approach combining Siamese neural networks (SNNs), graph neural networks (GNNs), autoencoders, and the OPTICS algorithm to create a comprehensive procedure named CREEK. This method is designed to uncover stellar structures in the Galactic halo. Initially, CREEK was trained on known globular clusters (GCs) and then applied to the dataset to identify stellar streams. CREEK successfully recovered 80% of the GCs present in the APOGEE dataset, re-identified several known stellar streams, and identified a potential new stream. Additionally, within highly populated stellar structures, CREEK can identify substructures that exhibit distinct chemical compositions and orbital energies. This approach provides an objective data-driven method for selecting stars associated with streams and stellar structures in general.