Low energy calibration in DUNE far detector prototypes

Abstract

The Deep Underground Neutrino Experiment (DUNE) is a next-generation long-baseline neutrino experiment. In addition to GeV-scale oscillation measurements (δCP, θ23 octant, mass ordering), DUNE features a low-energy (MeV-scale) program targeting solar, supernova burst (SNB), and Diffuse Supernova Background (DSNB) neutrinos. Accurate reconstruction and background understanding are critical. 39Ar β-decays, naturally present in LAr, provide a uniform background and can be used for calibration. This proceeding presents an analysis of isolated MeV-scale energy deposits in the ProtoDUNE-HD (PDHD) prototype. Using cosmic + beam data (run 28086), we analyze energy spectra and spatial distributions of 39Ar, 232Th, and 207Bi. A calibration factor cA = (3.9 0.3)× 10-2~MeV/ADC × tick and recombination factor R = 0.60 0.05 are extracted, consistent with expectations. The 207Bi source is spatially resolved with cm-level precision, and 232Th hot spots align with the field cage structure, offering further calibration potential. These results demonstrate PDHD capability for MeV-scale reconstruction, supporting DUNE low-energy physics goals.