Xenon doping of Liquid Argon in ProtoDUNE Single Phase

TL;DR

This study demonstrates that doping liquid argon with xenon in the ProtoDUNE-SP detector effectively shifts scintillation light to longer wavelengths, improves light collection uniformity, and does not impair charge collection, enhancing detector performance.

Contribution

It presents the largest xenon doping test in a LAr-TPC, showing efficient light shifting at low concentrations and confirming no adverse effects on charge collection.

Findings

Xenon doping shifts light emission from 128 nm to 178 nm.

Light collection efficiency improves with xenon doping.

Charge collection remains unaffected up to 20 ppm xenon.

Abstract

The Deep Underground Neutrino Experiment (DUNE) will be the next generation long-baseline neutrino experiment. The far detector is designed as a complex of four LAr-TPC (Liquid Argon Time Projection Chamber) modules with 17 kt of liquid argon each. The development and validation of the first far detector technology is pursued through ProtoDUNE Single Phase (ProtoDUNE-SP), a 770 t LAr-TPC at CERN Neutrino Platform. Crucial in DUNE is the Photon Detection System that will ensure the trigger of non-beam events - proton decay, supernova neutrino burst and BSM searches - and will improve the timing and calorimetry for neutrino beam events. Doping liquid argon with xenon is a known technique to shift the light emitted by argon (128 nm) to a longer wavelength (178 nm) to ease its detection. The largest xenon doping test ever performed in a LAr-TPC was carried out in ProtoDUNE-SP. From February to May 2020, a gradually increasing amount of xenon was injected to also compensate for the light loss due to air contamination. The response of such a large TPC has been studied using the ProtoDUNE-SP Photon Detection System (PDS) and a dedicated setup installed before the run. With the first it was possible to study the light collection efficiency with respect to the track position, while with the second it was possible to distinguish the xenon light from the LAr light. The light shifting mechanism proved to be highly efficient even at small xenon concentrations (< 20 ppm in mass) furthermore it allowed recovering the light quenched by pollutants. The light collection improved far from the detection plane, enhancing the photon detector response uniformity along the drift direction and confirming a longer Rayleigh scattering length for 178 nm photons, with respect to 128 nm ones. The charge collection by the TPC was monitored proving that xenon up to 20 ppm does not impact its performance.