arXiv : Snowmass 2021 Rare &amp; Precision Frontier (RF6): Dark Matter Production at Intensity-Frontier Experiments

Krnjaic, G.; Trojanowski, S.; Blinov, N.; Tsai, Y.-D.; Kelly, K.J.; Toro, N.; Batell, B.; Darme, L.; DeNiverville, P.; Berlin, A.; Hostert, M.; Hearty, C.; McKeen, D.; Harris, P.

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Preprint
Report number	arXiv:2207.00597 ; FERMILAB-PUB-22-497-T
Title	Snowmass 2021 Rare & Precision Frontier (RF6): Dark Matter Production at Intensity-Frontier Experiments
Author(s)	Krnjaic, G. (Fermilab ; Chicago U., Astron. Astrophys. Ctr. ; Chicago U., KICP) ; Toro, N. (SLAC) ; Berlin, A. (Fermilab) ; Batell, B. (Pittsburgh U.) ; Blinov, N. (Victoria U.) ; Darme, L. (IP2I, Lyon) ; DeNiverville, P. (Los Alamos) ; Harris, P. (MIT) ; Hearty, C. (British Columbia U. ; Victoria U.) ; Hostert, M. (Minnesota U. ; Minnesota U., Theor. Phys. Inst. ; Perimeter Inst. Theor. Phys.) ; Kelly, K.J. (CERN) ; McKeen, D. (TRIUMF) ; Trojanowski, S. (Warsaw, Copernicus Astron. Ctr. ; NCBJ, Warsaw) ; Tsai, Y.-D. (UC, Irvine)
Imprint	2022-07-01
Number of pages	45
Note	37 pages, 13 figures, comments and feedback welcome. Updated discussion of proton beam dump searches, minor edits to text and title for clarity. Core message unchanged
Subject category	hep-ex ; Particle Physics - Experiment ; astro-ph.CO ; Astrophysics and Astronomy ; hep-ph ; Particle Physics - Phenomenology
Abstract	Dark matter particles can be observably produced at intensity-frontier experiments, and opportunities in the next decade will explore important parameter space motivated by thermal DM models, the dark sector paradigm, and anomalies in data. This whitepaper describes the motivations, detection strategies, prospects and challenges for such searches, as well as synergies and complementarity both within RF6 and across HEP.
Other source	Inspire
Copyright/License	preprint: (License: arXiv nonexclusive-distrib 1.0)

$Thermal milestones for the kinetically mixed dark photon model, a key light DM benchmark (shown as black solid lines), along with exclusions from past experiments (gray shaded regions), projected sensitivities of future projects that are operating or have secured full funding (colored shaded regions), and projections for proposed experiments (unfilled curves). The (completed or proposed) experiments selected by Dark Matter New Initiatives (DMNI) program are shown by solid colored lines; other proposed experiments and upgrades that can be realized within a decade are shown as long-dashed colored lines if they are based in the US and/or have strong US leadership, or as short-dashed colored lines if they are primarily international efforts. Proposed experiments that are farther into the future are shown as thin dotted lines. As can be seen, the combination of operating experiments and the DMNI pre-project experiment (LDMX) can fully explore the thermal DM targets, considered a major milestone of dark-sector physics. Each line/region is color-coded according to which SM fermion coupling is employed to produce the DM. In variations of this model, some species may have suppressed couplings, making lines of different colors complementary in this extended model space. The figure focuses on a parameter slice with mediator mass fixed to 3$\times$ the DM mass, and dark-sector coupling $\alpha_D=0.5$. As these parameters are varied, the thermal milestones stay approximately fixed in the $y$ vs. $m_\chi$ plane (except in a near-resonant annihilation region) while experimental sensitivities generally improve, as illustrated for a subset of experiments in Fig.~\ref{sfig:darkPhotonThermalVaryR}.$ Show more plots

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Journalen skapades 2022-07-13, och modifierades senast 2024-10-02

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