A new investigation of electron neutrino appearance oscillations with improved sensitivity in the MiniBooNE+ experiment

TL;DR

The paper proposes adding scintillator to the MiniBooNE detector to improve sensitivity in neutrino oscillation studies, enabling neutron detection to distinguish between different interaction types and test the nature of the low-energy excess.

Contribution

It introduces a novel scintillator-based method to measure neutron fractions in MiniBooNE, enhancing the ability to identify the origin of the low-energy excess and improve oscillation sensitivity.

Findings

Neutron detection will differentiate NC and CC events.

Measurement of neutron fractions reduces systematic uncertainties.

Enhanced sensitivity to oscillation signals over 5 sigma.

Abstract

We propose the addition of scintillator to the existing MiniBooNE detector to allow a test of the neutral-current/charged-current (NC/CC) nature of the MiniBooNE low-energy excess. Scintillator will enable the reconstruction of 2.2 MeV $\gamma$s from neutron-capture on protons following neutrino interactions. Low-energy CC interactions where the oscillation excess is observed should have associated neutrons with less than a 10% probability. This is in contrast to the NC backgrounds that should have associated neutrons in approximately 50% of events. We will measure these neutron fractions with $\nu_\mu$ CC and NC events to eliminate that systematic uncertainty. This neutron-fraction measurement requires $6.5\times10^{20}$ protons on target delivered to MiniBooNE with scintillator added in order to increase the significance of an oscillation excess to over $5\sigma$. This new phase of MiniBooNE will also enable additional important studies such as the spin structure of nucleon ($\Delta s$) via NC elastic scattering, a low-energy measurement of the neutrino flux via $\numu ^{12}C \rightarrow \mu^{-} ^{12}N_\textrm{g.s.}$ scattering, and a test of the quasielastic assumption in neutrino energy reconstruction. These topics will yield important, highly-cited results over the next 5 years for a modest cost, and will help to train Ph.D. students and postdocs. This enterprise offers complementary information to that from the upcoming liquid Argon based MicroBooNE experiment. In addition, MicroBooNE is scheduled to receive neutrinos in early 2014, and there is minimal additional cost to also deliver beam to MiniBooNE.