First measurement of GaAs as a scintillating calorimeter: achievements and prospects

TL;DR

This study demonstrates the first use of GaAs as a scintillating calorimeter with dual heat and light detection, achieving high resolution and particle discrimination, opening new avenues for dark matter detection.

Contribution

First measurement of GaAs as a scintillating calorimeter with dual readout, showing promising resolution and particle discrimination capabilities for rare event detection.

Findings

Baseline resolution of 44.5 eV achieved with GaAs-2 crystal

Strong particle discrimination based on scintillation light

Unusual light yield behavior under alpha irradiation

Abstract

In this paper we present the first measurement of a Gallium Arsenide (GaAs) crystal as a scintillating calorimeter with dual heat and light readout within the DAREDEVIL project. The experimental setup features a 4.3 g GaAs (GaAs-1) crystal, operated at approximately 10 mK coupled with a Neutron Transmutation Doped (NTD) thermal sensor for phonon detection and an auxiliary calorimeter for the detection of scintillation light. For the GaAs-1 crystal, a baseline resolution of 121$\pm$ 2 eV has been achieved. While, with a 3.5 g GaAs (GaAs-2) crystal an even better baseline resolution of 44.5 $\pm$ 0.8 eV was achieved. Alpha and X-ray calibration sources were used to study the scintillation light response to different types of interacting radiation. The GaAs crystal exhibits a strong particle discrimination capability based on the emitted scintillation light, featuring a light yield (LY) of 0.9 $\pm$ 0.2 keV/MeV for $\alpha$ induced events and 0.07 $\pm$ 0.01 keV/MeV for $\beta$/$\gamma$ events, both measured at 1~MeV. The unusual luminescence behavior, i.e. more light being produced under irradiation by $\alpha$ particles warrants further investigation, particularly due to its potential to enhance sensitivity to low-energy nuclear recoils from light dark matter scattering.