Introducing the DREAMS Project: DaRk mattEr and Astrophysics with Machine Learning and Simulations

Jonah C. Rose; Paul Torrey; Francisco Villaescusa-Navarro; Mariangela Lisanti; Tri Nguyen; Sandip Roy; Kassidy E. Kollmann; Mark Vogelsberger; Francis Yan Cyr-Racine; Mikhail V. Medvedev; Shy Genel; Daniel Anglés-Alcázar; Nitya Kallivayalil; Bonny Y. Wang; Belén Costanza; Stephanie O’Neil; Cian Roche; Soumyodipta Karmakar; Alex M. Garcia; Ryan Low; Shurui Lin; Olivia Mostow; Akaxia Cruz; Andrea Caputo; Arya Farahi; Julian B. Muñoz; Lina Necib; Romain Teyssier; Julianne J. Dalcanton; David Spergel

doi:10.3847/1538-4357/adb8e5

Introducing the DREAMS Project: DaRk mattEr and Astrophysics with Machine Learning and Simulations

Jonah C. Rose, Paul Torrey, Francisco Villaescusa-Navarro, Mariangela Lisanti, Tri Nguyen, Sandip Roy, Kassidy E. Kollmann, Mark Vogelsberger, Francis Yan Cyr-Racine, Mikhail V. Medvedev, Shy Genel, Daniel Anglés-Alcázar, Nitya Kallivayalil, Bonny Y. Wang, Belén Costanza, Stephanie O’Neil, Cian Roche, Soumyodipta Karmakar, Alex M. Garcia, Ryan LowShurui Lin, Olivia Mostow, Akaxia Cruz, Andrea Caputo, Arya Farahi, Julian B. Muñoz, Lina Necib, Romain Teyssier, Julianne J. Dalcanton, David Spergel

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Abstract

We introduce the DaRk mattEr and Astrophysics with Machine learning and Simulations (DREAMS) project, an innovative approach to understanding the astrophysical implications of alternative dark matter (DM) models and their effects on galaxy formation and evolution. The DREAMS project will ultimately comprise thousands of cosmological hydrodynamic simulations that simultaneously vary over DM physics, astrophysics, and cosmology in modeling a range of systems—from galaxy clusters to ultra-faint satellites. Such extensive simulation suites can provide adequate training sets for machine-learning-based analyses. This paper introduces two new cosmological hydrodynamical suites of warm dark matter (WDM), each comprising 1024 simulations generated using the arepo code. One suite consists of uniform-box simulations covering a ( 25 h − 1 Mpc ) 3 volume, while the other consists of Milky Way zoom-ins with sufficient resolution to capture the properties of classical satellites. For each simulation, the WDM particle mass is varied along with the initial density field and several parameters controlling the strength of baryonic feedback within the IllustrisTNG model. We provide two examples, separately utilizing emulators and convolutional neural networks, to demonstrate how such simulation suites can be used to disentangle the effects of DM and baryonic physics on galactic properties. The DREAMS project can be extended further to include different DM models, galaxy formation physics, and astrophysical targets. In this way, it will provide an unparalleled opportunity to characterize uncertainties on predictions for small-scale observables, leading to robust predictions for testing the particle physics nature of DM on these scales.

Original language	English (US)
Article number	68
Journal	Astrophysical Journal
Volume	982
Issue number	2
DOIs	https://doi.org/10.3847/1538-4357/adb8e5
State	Published - Apr 1 2025

All Science Journal Classification (ASJC) codes

Astronomy and Astrophysics
Space and Planetary Science

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Rose, J. C., Torrey, P., Villaescusa-Navarro, F., Lisanti, M., Nguyen, T., Roy, S., Kollmann, K. E., Vogelsberger, M., Cyr-Racine, F. Y., Medvedev, M. V., Genel, S., Anglés-Alcázar, D., Kallivayalil, N., Wang, B. Y., Costanza, B., O’Neil, S., Roche, C., Karmakar, S., Garcia, A. M., ... Spergel, D. (2025). Introducing the DREAMS Project: DaRk mattEr and Astrophysics with Machine Learning and Simulations. Astrophysical Journal, 982(2), Article 68. https://doi.org/10.3847/1538-4357/adb8e5

@article{102e840e9f6e403b8be5bce25f0b945b,

title = "Introducing the DREAMS Project: DaRk mattEr and Astrophysics with Machine Learning and Simulations",

abstract = "We introduce the DaRk mattEr and Astrophysics with Machine learning and Simulations (DREAMS) project, an innovative approach to understanding the astrophysical implications of alternative dark matter (DM) models and their effects on galaxy formation and evolution. The DREAMS project will ultimately comprise thousands of cosmological hydrodynamic simulations that simultaneously vary over DM physics, astrophysics, and cosmology in modeling a range of systems—from galaxy clusters to ultra-faint satellites. Such extensive simulation suites can provide adequate training sets for machine-learning-based analyses. This paper introduces two new cosmological hydrodynamical suites of warm dark matter (WDM), each comprising 1024 simulations generated using the arepo code. One suite consists of uniform-box simulations covering a ( 25 h − 1 Mpc ) 3 volume, while the other consists of Milky Way zoom-ins with sufficient resolution to capture the properties of classical satellites. For each simulation, the WDM particle mass is varied along with the initial density field and several parameters controlling the strength of baryonic feedback within the IllustrisTNG model. We provide two examples, separately utilizing emulators and convolutional neural networks, to demonstrate how such simulation suites can be used to disentangle the effects of DM and baryonic physics on galactic properties. The DREAMS project can be extended further to include different DM models, galaxy formation physics, and astrophysical targets. In this way, it will provide an unparalleled opportunity to characterize uncertainties on predictions for small-scale observables, leading to robust predictions for testing the particle physics nature of DM on these scales.",

author = "Rose, \{Jonah C.\} and Paul Torrey and Francisco Villaescusa-Navarro and Mariangela Lisanti and Tri Nguyen and Sandip Roy and Kollmann, \{Kassidy E.\} and Mark Vogelsberger and Cyr-Racine, \{Francis Yan\} and Medvedev, \{Mikhail V.\} and Shy Genel and Daniel Angl{\'e}s-Alc{\'a}zar and Nitya Kallivayalil and Wang, \{Bonny Y.\} and Bel{\'e}n Costanza and Stephanie O{\textquoteright}Neil and Cian Roche and Soumyodipta Karmakar and Garcia, \{Alex M.\} and Ryan Low and Shurui Lin and Olivia Mostow and Akaxia Cruz and Andrea Caputo and Arya Farahi and Mu{\~n}oz, \{Julian B.\} and Lina Necib and Romain Teyssier and Dalcanton, \{Julianne J.\} and David Spergel",

note = "Publisher Copyright: {\textcopyright} 2025. The Author(s). Published by the American Astronomical Society.",

year = "2025",

month = apr,

day = "1",

doi = "10.3847/1538-4357/adb8e5",

language = "English (US)",

volume = "982",

journal = "Astrophysical Journal",

issn = "0004-637X",

publisher = "American Astronomical Society",

number = "2",

}

Rose, JC, Torrey, P, Villaescusa-Navarro, F, Lisanti, M, Nguyen, T, Roy, S, Kollmann, KE, Vogelsberger, M, Cyr-Racine, FY, Medvedev, MV, Genel, S, Anglés-Alcázar, D, Kallivayalil, N, Wang, BY, Costanza, B, O’Neil, S, Roche, C, Karmakar, S, Garcia, AM, Low, R, Lin, S, Mostow, O, Cruz, A, Caputo, A, Farahi, A, Muñoz, JB, Necib, L, Teyssier, R, Dalcanton, JJ & Spergel, D 2025, 'Introducing the DREAMS Project: DaRk mattEr and Astrophysics with Machine Learning and Simulations', Astrophysical Journal, vol. 982, no. 2, 68. https://doi.org/10.3847/1538-4357/adb8e5

TY - JOUR

T1 - Introducing the DREAMS Project

T2 - DaRk mattEr and Astrophysics with Machine Learning and Simulations

AU - Rose, Jonah C.

AU - Torrey, Paul

AU - Villaescusa-Navarro, Francisco

AU - Lisanti, Mariangela

AU - Nguyen, Tri

AU - Roy, Sandip

AU - Kollmann, Kassidy E.

AU - Vogelsberger, Mark

AU - Cyr-Racine, Francis Yan

AU - Medvedev, Mikhail V.

AU - Genel, Shy

AU - Anglés-Alcázar, Daniel

AU - Kallivayalil, Nitya

AU - Wang, Bonny Y.

AU - Costanza, Belén

AU - O’Neil, Stephanie

AU - Roche, Cian

AU - Karmakar, Soumyodipta

AU - Garcia, Alex M.

AU - Low, Ryan

AU - Lin, Shurui

AU - Mostow, Olivia

AU - Cruz, Akaxia

AU - Caputo, Andrea

AU - Farahi, Arya

AU - Muñoz, Julian B.

AU - Necib, Lina

AU - Teyssier, Romain

AU - Dalcanton, Julianne J.

AU - Spergel, David

PY - 2025/4/1

Y1 - 2025/4/1

N2 - We introduce the DaRk mattEr and Astrophysics with Machine learning and Simulations (DREAMS) project, an innovative approach to understanding the astrophysical implications of alternative dark matter (DM) models and their effects on galaxy formation and evolution. The DREAMS project will ultimately comprise thousands of cosmological hydrodynamic simulations that simultaneously vary over DM physics, astrophysics, and cosmology in modeling a range of systems—from galaxy clusters to ultra-faint satellites. Such extensive simulation suites can provide adequate training sets for machine-learning-based analyses. This paper introduces two new cosmological hydrodynamical suites of warm dark matter (WDM), each comprising 1024 simulations generated using the arepo code. One suite consists of uniform-box simulations covering a ( 25 h − 1 Mpc ) 3 volume, while the other consists of Milky Way zoom-ins with sufficient resolution to capture the properties of classical satellites. For each simulation, the WDM particle mass is varied along with the initial density field and several parameters controlling the strength of baryonic feedback within the IllustrisTNG model. We provide two examples, separately utilizing emulators and convolutional neural networks, to demonstrate how such simulation suites can be used to disentangle the effects of DM and baryonic physics on galactic properties. The DREAMS project can be extended further to include different DM models, galaxy formation physics, and astrophysical targets. In this way, it will provide an unparalleled opportunity to characterize uncertainties on predictions for small-scale observables, leading to robust predictions for testing the particle physics nature of DM on these scales.

AB - We introduce the DaRk mattEr and Astrophysics with Machine learning and Simulations (DREAMS) project, an innovative approach to understanding the astrophysical implications of alternative dark matter (DM) models and their effects on galaxy formation and evolution. The DREAMS project will ultimately comprise thousands of cosmological hydrodynamic simulations that simultaneously vary over DM physics, astrophysics, and cosmology in modeling a range of systems—from galaxy clusters to ultra-faint satellites. Such extensive simulation suites can provide adequate training sets for machine-learning-based analyses. This paper introduces two new cosmological hydrodynamical suites of warm dark matter (WDM), each comprising 1024 simulations generated using the arepo code. One suite consists of uniform-box simulations covering a ( 25 h − 1 Mpc ) 3 volume, while the other consists of Milky Way zoom-ins with sufficient resolution to capture the properties of classical satellites. For each simulation, the WDM particle mass is varied along with the initial density field and several parameters controlling the strength of baryonic feedback within the IllustrisTNG model. We provide two examples, separately utilizing emulators and convolutional neural networks, to demonstrate how such simulation suites can be used to disentangle the effects of DM and baryonic physics on galactic properties. The DREAMS project can be extended further to include different DM models, galaxy formation physics, and astrophysical targets. In this way, it will provide an unparalleled opportunity to characterize uncertainties on predictions for small-scale observables, leading to robust predictions for testing the particle physics nature of DM on these scales.

UR - https://www.scopus.com/pages/publications/105000461800

UR - https://www.scopus.com/inward/citedby.url?scp=105000461800&partnerID=8YFLogxK

U2 - 10.3847/1538-4357/adb8e5

DO - 10.3847/1538-4357/adb8e5

M3 - Article

AN - SCOPUS:105000461800

SN - 0004-637X

VL - 982

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 2

M1 - 68

ER -

Introducing the DREAMS Project: DaRk mattEr and Astrophysics with Machine Learning and Simulations

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