First Measurement of Charged-Current 1 Muon 2 Proton 0 Pion Single Differential Cross-Sections on Argon-40 at 0.8 GeV Average Neutrino Energy with the MicroBooNE Detector

Ph.D. Final Oral Exam

When: Friday, April 1, 11am

Where: Goedecke Conference Room

First Measurement of Charged-Current 1 Muon 2 Proton 0 Pion Single Differential Cross-Sections on Argon-40 at 0.8 GeV Average Neutrino Energy with the MicroBooNE Detector

Samantha Sword-Fehlberg

Abstract

Constraining systematic uncertainties that arise from neutrino-nucleon cross-section modeling is critical for upcoming neutrino oscillation experiments. Neutrino interactions that lead to the ejection of 2 particles from the target nucleus, leaving the nucleus with 2 holes, are one cross-section of interest. These instances, known as 2-particle 2-hole (2p2h) states, can be produced either by neutrino interaction modes or from the influence of nuclear physics on the neutrino interaction. While there are many theoretical models that attempt to describe the nature of 2p2h states, very few experimental measurements of this process exist, making it difficult to benchmark theoretical calculations. Furthermore, no high statistic cross-section measurements of 2p2h states exist on $^{40}$Ar, the target nucleus of many current and next generation neutrino oscillation experiments. This analysis aims to address this issue by providing the first high-statistic single differential cross-section measurements of 2p2h states. Using data collected from the first 3 years of running of the MicroBooNE experiment, we select $\nu_\mu$ charged-current interaction events that produce a single muon, 2 protons, and no pions in the final state (CC1$\mu$2p0$\pi$). The single differential cross-section is then extracted as a function of a variety of physics variables and compared to theoretical predictions from several event generator model sets.