Low-energy nuclear recoil calibration of the LUX-ZEPLIN experiment with a photoneutron source

Abstract

The LZ experiment is a liquid xenon time-projection chamber (TPC) searching for evidence of particle dark matter interactions. In the simplest assumption of elastic scattering, many dark matter models predict an energy spectrum which rises quasi-exponentially with decreasing energy transfer to a target atom. LZ expects to detect coherent neutrino-nucleus scattering of 8B solar neutrinos, the signal from which is very similar to a dark matter particle with mass of about 5.5 GeV/c2, which result in typical nuclear recoil energies of <5 keVnr. Therefore, it is of crucial importance to calibrate the response of recoiling xenon nuclei to keV-energy recoils. This analysis details the first in situ photoneutron calibration of the LZ detector and probes its response in this energy regime.