Millicharged particles in neutrino experiments

Article
Report number	arXiv:1806.03310 ; FERMILAB-PUB-18-631-A
Title	Millicharged particles in neutrino experiments
Author(s)	Magill, Gabriel (Perimeter Inst. Theor. Phys. ; McMaster U.) ; Plestid, Ryan (Perimeter Inst. Theor. Phys. ; McMaster U.) ; Pospelov, Maxim (Perimeter Inst. Theor. Phys. ; Victoria U. ; CERN) ; Tsai, Yu-Dai (Cornell U., LEPP ; Fermilab)
Publication	2019-02-20
Imprint	2018-06-08
Number of pages	7
Note	7 pages, 1 figure, 1 table, matches PRL version, references added
In:	Phys. Rev. Lett. 122 (2019) 071801
DOI	10.1103/PhysRevLett.122.071801
Subject category	hep-ph ; Particle Physics - Phenomenology ; hep-ex ; Particle Physics - Experiment
Abstract	We set constraints and future sensitivity projections on millicharged particles (MCPs) based on electron scattering data in numerous neutrino experiments, starting with MiniBooNE and the Liquid Scintillator Neutrino Detector (LSND). Both experiments are found to provide new (and leading) constraints in certain MCP mass windows: 5 - 35 MeV for LSND and 100 - 180 MeV for MiniBooNE. Furthermore, we provide projections for the ongoing Fermilab SBN program, the Deep Underground Neutrino Experiment (DUNE), and the proposed Search for Hidden Particles (SHiP) experiment. In the SBN program, SBND and MicroBooNE have the capacity to provide the leading bounds in the 100 - 300 MeV mass regime. DUNE and SHiP are capable of probing parameter space for MCP masses in the range of 5 MeV - 5 GeV that is significantly beyond the reach of existing bounds, including those from collider searches and, in the case of DUNE, the SLAC mQ experiment.
Copyright/License	preprint: (License: CC BY-NC-SA 4.0) publication: © 2019-2024 authors (License: CC-BY-4.0)

$Exclusion curves for fermionic mCPs (results are broadly similar for scalars). Existing data is shown as solid lines, while projections are shown as dashed curves. The kinematic reach of a given experiment is set by the heaviest meson of interest it can produce. This is $\pi^0$ for LSND, $\eta$ for the Booster experiments, and $\Upsilon$ for DUNE. At SHiP, Drell-Yan production extends the kinematic reach to roughly $10\GeV$. The sensitivity of each experiment can be understood via \cref{eq:NumberSignalEvents} while the relevant parameters for each experiment are summarized in \cref{tab:summary}. The bound on $N_\text{eff}$ \cite{Boehm:2013jpa} comes from changing the effective number of neutrinos during BBN, while the SLAC mQ and collider bounds are taken from \cite{Prinz:1998ua} and \cite{Davidson:2000hf,Haas:2014dda} respectively. The projected sensitivities at milliQan are from \cite{Ball:2016zrp,Haas:2014dda}. Our exclusions apply independently of the existence of a dark photon, which would only introduce additional constraints \cite{Berlin:2018sjs}.$ $Exclusion curves for fermionic MCPs (results are broadly similar for scalars). Existing data is shown as solid lines, while projections are shown as dashed curves. The kinematic reach of a given experiment is set by the heaviest meson of interest it can produce. This is $\pi^0$ for LSND, $\eta$ for the Booster experiments, and $\Upsilon$ for DUNE. At SHiP, Drell-Yan production extends the kinematic reach to roughly $10\GeV$. The sensitivity of each experiment can be understood via \cref{eq:NumberSignalEvents} while the relevant parameters for each experiment are summarized in \cref{tab:summary}. The bound on $N_\text{eff}$ \cite{Boehm:2013jpa} comes from changing the effective number of neutrinos, while the SLAC bound (below $\sim$ 100 MeV) and the collider bound (extends up to $\sim$ 30 GeV in the plot) are taken from \cite{Prinz:1998ua} and \cite{Davidson:2000hf,Haas:2014dda} respectively. The projected sensitivities at milliQan are from \cite{Ball:2016zrp,Haas:2014dda}. Our exclusions apply independently of the existence of a dark photon, which introduces additional constraints \cite{Berlin:2018sjs}.$

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