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Main Authors: Vladimir, Ze'ev, Osinga, Calvin, Diemer, Benedikt, Salazar, Edgar M., Rozo, Eduardo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.09146
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author Vladimir, Ze'ev
Osinga, Calvin
Diemer, Benedikt
Salazar, Edgar M.
Rozo, Eduardo
author_facet Vladimir, Ze'ev
Osinga, Calvin
Diemer, Benedikt
Salazar, Edgar M.
Rozo, Eduardo
contents Dark matter halos are typically defined as spheres that enclose some overdensity, but these sharp, somewhat arbitrary boundaries introduce non-physical artifacts such as backsplash halos, pseudo-evolution, and an incomplete accounting of halo mass. A more physically motivated alternative is to define halos as the collection of particles that are physically orbiting within their potential well. However, existing methods to classify particles as orbiting or infalling suffer from trade-offs between accuracy, computational cost, and generalizability across cosmologies. We present an efficient, yet accurate, supervised machine learning approach using decision trees. The classification is based on only the particle radii and velocities at two epochs. Compared to detailed analysis of particle trajectories, we find that our model matches the classification of 97\% of particles. Consequently, we are able to quickly and accurately reproduce the density profiles of the orbiting and infalling components out to many virial radii. We demonstrate that our model generalizes to a significantly different cosmology that lies outside the training dataset. We make publicly available both our final model and the code to train similar models.
format Preprint
id arxiv_https___arxiv_org_abs_2506_09146
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Distinguishing Orbiting and Infalling Dark Matter Particles with Machine Learning
Vladimir, Ze'ev
Osinga, Calvin
Diemer, Benedikt
Salazar, Edgar M.
Rozo, Eduardo
Cosmology and Nongalactic Astrophysics
Dark matter halos are typically defined as spheres that enclose some overdensity, but these sharp, somewhat arbitrary boundaries introduce non-physical artifacts such as backsplash halos, pseudo-evolution, and an incomplete accounting of halo mass. A more physically motivated alternative is to define halos as the collection of particles that are physically orbiting within their potential well. However, existing methods to classify particles as orbiting or infalling suffer from trade-offs between accuracy, computational cost, and generalizability across cosmologies. We present an efficient, yet accurate, supervised machine learning approach using decision trees. The classification is based on only the particle radii and velocities at two epochs. Compared to detailed analysis of particle trajectories, we find that our model matches the classification of 97\% of particles. Consequently, we are able to quickly and accurately reproduce the density profiles of the orbiting and infalling components out to many virial radii. We demonstrate that our model generalizes to a significantly different cosmology that lies outside the training dataset. We make publicly available both our final model and the code to train similar models.
title Distinguishing Orbiting and Infalling Dark Matter Particles with Machine Learning
topic Cosmology and Nongalactic Astrophysics
url https://arxiv.org/abs/2506.09146