Snowmass2021 cosmic frontier white paper: Ultraheavy particle dark matter-Reference-Cited by-同舟云学术

Snowmass2021 cosmic frontier white paper: Ultraheavy particle dark matter

Published:2023-11-06 Issue:4 Volume:6 Page:
ISSN:2666-9366
Container-title:SciPost Physics Core
language:
Short-container-title:SciPost Phys. Core

Author:

Carney Daniel¹,Raj Nirmal²,Bai Yang³,Berger Joshua⁴,Blanco Carlos⁵⁶,Bramante Joseph⁷⁸,Cappiello Christopher⁸,Dutra Maíra⁹,Ebadi Reza¹⁰,Engel Kristi¹⁰,Kolb Edward¹¹,Harding J. Patrick¹²,Kumar Jason¹³,Krnjaic Gordan¹⁴¹¹,Lang Rafael F.¹⁵,Leane Rebecca K.¹⁶¹⁷,Lehmann Benjamin V.¹⁸,Li Shengchao¹⁵,Long Andrew J.¹⁹,Mohlabeng Gopolang⁷⁸,Olcina Ibles¹²⁰,Pueschel Elisa²¹,Rodd Nicholas L.²²,Rott Carsten²³²⁴,Sengupta Dipan²⁵²⁶,Shakya Bibhushan²¹,Walsworth Ronald L.¹⁰,Westerdale Shawn⁶

Affiliation:

1. Lawrence Berkeley National Laboratory

2. Indian Institute of Science Bangalore

3. University of Wisconsin–Madison

4. Colorado State University

5. Stockholm University

6. Princeton University

7. Perimeter Institute

8. Queen's University

9. Carleton University

10. University of Maryland, College Park

11. University of Chicago

12. Los Alamos National Laboratory

13. University of Hawaii System

14. Fermi National Accelerator Laboratory

15. Purdue University

16. Kavli Institute for Particle Astrophysics and Cosmology

17. SLAC National Accelerator Laboratory

18. University of California, Santa Cruz

19. Rice University

20. University of California, Berkeley

21. Deutsche Elektronen-Synchrotron DESY

22. European Organization for Nuclear Research

23. Sungkyunkwan University

24. University of Utah

25. University of Adelaide

26. University of California, San Diego

Abstract

We outline the unique opportunities and challenges in the search for “ultraheavy” dark matter candidates with masses between roughly 10 TeV and the Planck scale

m_{\rm pl} ≈ 10^{16}

TeV. This mass range presents a wide and relatively unexplored dark matter parameter space, with a rich space of possible models and cosmic histories. We emphasize that both current detectors and new, targeted search techniques, via both direct and indirect detection, are poised to contribute to searches for ultraheavy particle dark matter in the coming decade. We highlight the need for new developments in this space, including new analyses of current and imminent direct and indirect experiments targeting ultraheavy dark matter and development of new, ultra-sensitive detector technologies like next-generation liquid noble detectors, neutrino experiments, and specialized quantum sensing techniques.

Publisher

Stichting SciPost

Subject

Statistical and Nonlinear Physics,Atomic and Molecular Physics, and Optics,Nuclear and High Energy Physics,Condensed Matter Physics

Link

https://scipost.org/10.21468/SciPostPhysCore.6.4.075/pdf

Reference213 articles.

1. Planck2018 results

2. Decaying particles do not ‘‘heat up’’ the Universe

3. Unitarity limits on the mass and radius of dark-matter particles

4. Superheavy thermal dark matter and primordial asymmetries

5. Homeopathic Dark Matter, or how diluted heavy substances produce high energy cosmic rays

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