Primary scintillation yield in gaseous Xe for electrons and alpha-particles

Xenon scintillation has been widely used in rare event detection experiments, such as in neutrinoless double beta decay, double electron capture and dark matter searches. Nonetheless, experimental values for primary scintillation yield in gaseous xenon (GXe) remain scarce and dispersed. The mean energy required to produce a scintillation photon, w_sc in GXe in the absence of recombination has been measured to be in the range of 34-111 eV. Lower w_sc-values are often reported for alpha-particles when compared to electrons produced by gamma- or x-rays, being this difference not understood. We carried out a systematic study on the absolute primary scintillation yield in GXe under reduced electric fields in the 70-300 V/cm/bar range and near atmospheric pressure, 1.2 bar, supported by a robust geometrical efficiency simulation model. Neglecting the 3rd continuum emission, a mean w_sc-value of 38.7 [+- 0.6 (sta.)] [(- 7.2) (+ 7.7) (sys.)] eV was obtained for x/gamma-rays in the 5.9-60 keV energy range and alpha-particles in the 1.5-2.5 MeV range, no significant dependency neither on radiation type nor on energy has been observed. If the Xe 3rd continuum emission is to be considered, the average energy to produce a 2nd and a 3rd continuum photon was calculated as w_2nd = 43.5 [+- 0.7 (sta.)][(- 8.1)(+ 8.7) (sys.)] eV and w_3rd = 483 [+- 7 (sta.)][(- 105)(+ 110) (sys.)] eV, respectively, while the energy to produce either a 3rd or a 2nd continuum photon is w_(2nd + 3rd) = 39.9 [+- 0.6 (sta.)] [(- 7.4) (+ 8.0) (sys.)] eV. Our experimental w_sc-values agree with both state-of-art simulations and literature data obtained for alpha-particles. The discrepancy between our results and the experimental values found in the literature for x/gamma-rays is discussed and attributed to undressed large systematic errors in previous studies.