Abstract
Nearly-sterile neutrinos with masses in the MeV range and below would be produced in the beam of the Short-Baseline Neutrino (SBN) program at Fermilab. In this article, we study the potential for SBN to discover these particles through their subsequent decays in its detectors. We discuss the decays which will be visible at SBN in a minimal and non-minimal extension of the Standard Model, and perform simulations to compute the parameter space constraints which could be placed in the absence of a signal. We demonstrate that the SBN programme can extend existing bounds on well constrained channels such as N → νl+l− and N → l±π∓ while, thanks to the strong particle identification capabilities of liquid-Argon technology, also place bounds on often neglected channels such as N → νγ and N → νπ0. Furthermore, we consider the phenomenological impact of improved event timing information at the three detectors. As well as considering its role in background reduction, we note that if the light-detection systems in SBND and ICARUS can achieve nanosecond timing resolution, the effect of finite sterile neutrino mass could be directly observable, providing a smoking-gun signature for this class of models. We stress throughout that the search for heavy nearly-sterile neutrinos is a complementary new physics analysis to the search for eV-scale oscillations, and would extend the BSM programme of SBN while requiring no beam or detector modifications.
Highlights
Background reductionIn order to estimate the impact of potential backgrounds we have performed a Monte-Carlo analysis using the neutrino event generator GENIE [57]
For larger enhancements, the lower-bound on the mixing-matrix element must be considered. This bound lies at large values of |U |2, and is not shown in the plots, but it is affected by an enhanced decay rate and can become relevant of reasonable enhancements. This can be seen in the left panel of figure 8, where we show the region of parameter space that Short-Baseline Neutrino (SBN) could exclude when studying the decay mode N Ñ νeeas we increase its decay rate by factors of 10, 102, 103 and 104
We have studied the prospects for the measurement of MeV-scale sterile neutrinos at the Fermilab Short-Baseline Neutrino program
Summary
The most general renormalizable lagrangian extending the SM to include a new gaugesinglet fermion N is given by LN “. Much work has been done understanding the phenomenology of such novel neutral states, which varies significantly over their large parameter spaces Lagrangians similar to this have been used in the literature for a wide range of purposes. In the minimal lagrangian in eq (2.1), the only direct couplings to new sterile flavour eigenstates are neutrino-Higgs interactions. These couplings generate off-diagonal neutrino bilinears below the electroweak symmetry breaking scale, leading to mixing-mediated interactions with SM gauge bosons for the mostly neutral mass eigenstate. This allows them to be produced in and decay via SM gauge interactions, albeit suppressed by the mixing angle. We will return to the idea of a nonminimal lagrangian in section 2.2.2 when discussing the decay modes of N
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