Constraints on self-interaction cross-sections of dark matter in universal bound states from direct detection

CRESST Collaboration

doi:10.1140/epjc/s10052-024-13472-4

Constraints on self-interaction cross-sections of dark matter in universal bound states from direct detection

CRESST Collaboration

Chair of Experimental Astroparticle Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Λ-Cold Dark Matter (ΛCDM) has been successful at explaining the large-scale structures in the universe but faces severe issues on smaller scales when compared to observations. Introducing self-interactions between dark matter particles claims to provide a solution to the small-scale issues in the ΛCDM simulations while being consistent with the observations at large scales. The existence of the energy region in which these self-interactions between dark matter particles come close to saturating the S-wave unitarity bound can result in the formation of dark matter bound states called darkonium. In this scenario, all the low energy scattering properties are determined by a single parameter, the inverse scattering length γ. In this work, we set bounds on γ by studying the impact of darkonium on the observations at direct detection experiments using data from CRESST-III and XENON1T. The exclusion limits on γ are then subsequently converted to exclusion limits on the self-interaction cross-section and compared with the constraints from astrophysics and N-body simulations.

Original language	English
Article number	1170
Journal	European Physical Journal C
Volume	84
Issue number	11
DOIs	https://doi.org/10.1140/epjc/s10052-024-13472-4
State	Published - Nov 2024

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10.1140/epjc/s10052-024-13472-4

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@article{fd6f6a4d2c79458e8c5f4eaa643ff8c0,

title = "Constraints on self-interaction cross-sections of dark matter in universal bound states from direct detection",

abstract = "Λ-Cold Dark Matter (ΛCDM) has been successful at explaining the large-scale structures in the universe but faces severe issues on smaller scales when compared to observations. Introducing self-interactions between dark matter particles claims to provide a solution to the small-scale issues in the ΛCDM simulations while being consistent with the observations at large scales. The existence of the energy region in which these self-interactions between dark matter particles come close to saturating the S-wave unitarity bound can result in the formation of dark matter bound states called darkonium. In this scenario, all the low energy scattering properties are determined by a single parameter, the inverse scattering length γ. In this work, we set bounds on γ by studying the impact of darkonium on the observations at direct detection experiments using data from CRESST-III and XENON1T. The exclusion limits on γ are then subsequently converted to exclusion limits on the self-interaction cross-section and compared with the constraints from astrophysics and N-body simulations.",

author = "CRESST Collaboration and G. Angloher and S. Banik and G. Benato and A. Bento and A. Bertolini and R. Breier and C. Bucci and J. Burkhart and E. Cipelli and L. Canonica and A. D{\textquoteright}Addabbo and {Di Lorenzo}, S. and L. Einfalt and A. Erb and Feilitzsch, {F. V.} and S. Fichtinger and D. Fuchs and A. Garai and Ghete, {V. M.} and P. Gorla and Guillaumon, {P. V.} and S. Gupta and D. Hauff and M. Je{\v s}kovsk{\'y} and J. Jochum and M. Kaznacheeva and A. Kinast and S. Kuckuk and H. Kluck and H. Kraus and A. Langenk{\"a}mper and M. Mancuso and L. Marini and B. Mauri and L. Meyer and V. Mokina and M. Olmi and T. Ortmann and C. Pagliarone and L. Pattavina and F. Petricca and W. Potzel and P. Povinec and F. Pr{\"o}bst and F. Pucci and F. Reindl and J. Rothe and K. Sch{\"a}ffner and J. Schieck and S. Sch{\"o}nert",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = nov,

doi = "10.1140/epjc/s10052-024-13472-4",

language = "English",

volume = "84",

journal = "European Physical Journal C",

issn = "1434-6044",

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T1 - Constraints on self-interaction cross-sections of dark matter in universal bound states from direct detection

AU - CRESST Collaboration

AU - Angloher, G.

AU - Banik, S.

AU - Benato, G.

AU - Bento, A.

AU - Bertolini, A.

AU - Breier, R.

AU - Bucci, C.

AU - Burkhart, J.

AU - Cipelli, E.

AU - Canonica, L.

AU - D’Addabbo, A.

AU - Di Lorenzo, S.

AU - Einfalt, L.

AU - Erb, A.

AU - Feilitzsch, F. V.

AU - Fichtinger, S.

AU - Fuchs, D.

AU - Garai, A.

AU - Ghete, V. M.

AU - Gorla, P.

AU - Guillaumon, P. V.

AU - Gupta, S.

AU - Hauff, D.

AU - Ješkovský, M.

AU - Jochum, J.

AU - Kaznacheeva, M.

AU - Kinast, A.

AU - Kuckuk, S.

AU - Kluck, H.

AU - Kraus, H.

AU - Langenkämper, A.

AU - Mancuso, M.

AU - Marini, L.

AU - Mauri, B.

AU - Meyer, L.

AU - Mokina, V.

AU - Olmi, M.

AU - Ortmann, T.

AU - Pagliarone, C.

AU - Pattavina, L.

AU - Petricca, F.

AU - Potzel, W.

AU - Povinec, P.

AU - Pröbst, F.

AU - Pucci, F.

AU - Reindl, F.

AU - Rothe, J.

AU - Schäffner, K.

AU - Schieck, J.

AU - Schönert, S.

PY - 2024/11

Y1 - 2024/11

N2 - Λ-Cold Dark Matter (ΛCDM) has been successful at explaining the large-scale structures in the universe but faces severe issues on smaller scales when compared to observations. Introducing self-interactions between dark matter particles claims to provide a solution to the small-scale issues in the ΛCDM simulations while being consistent with the observations at large scales. The existence of the energy region in which these self-interactions between dark matter particles come close to saturating the S-wave unitarity bound can result in the formation of dark matter bound states called darkonium. In this scenario, all the low energy scattering properties are determined by a single parameter, the inverse scattering length γ. In this work, we set bounds on γ by studying the impact of darkonium on the observations at direct detection experiments using data from CRESST-III and XENON1T. The exclusion limits on γ are then subsequently converted to exclusion limits on the self-interaction cross-section and compared with the constraints from astrophysics and N-body simulations.

AB - Λ-Cold Dark Matter (ΛCDM) has been successful at explaining the large-scale structures in the universe but faces severe issues on smaller scales when compared to observations. Introducing self-interactions between dark matter particles claims to provide a solution to the small-scale issues in the ΛCDM simulations while being consistent with the observations at large scales. The existence of the energy region in which these self-interactions between dark matter particles come close to saturating the S-wave unitarity bound can result in the formation of dark matter bound states called darkonium. In this scenario, all the low energy scattering properties are determined by a single parameter, the inverse scattering length γ. In this work, we set bounds on γ by studying the impact of darkonium on the observations at direct detection experiments using data from CRESST-III and XENON1T. The exclusion limits on γ are then subsequently converted to exclusion limits on the self-interaction cross-section and compared with the constraints from astrophysics and N-body simulations.

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U2 - 10.1140/epjc/s10052-024-13472-4

DO - 10.1140/epjc/s10052-024-13472-4

M3 - Article

AN - SCOPUS:85210024575

SN - 1434-6044

VL - 84

JO - European Physical Journal C

JF - European Physical Journal C

IS - 11

M1 - 1170

ER -

Constraints on self-interaction cross-sections of dark matter in universal bound states from direct detection

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