Effects of increasing size and changing europium activator concentration in KCaI3 scintillator crystals

Abstract

KCaI3:Eu crystals have been identified as very promising for use in spectroscopic detector applications related to nuclear nonproliferation and domestic security efforts. Initial studies have shown for small crystals a few mm3 in size with 3% europium dopant concentration, a high light yield of >70,000ph/MeV and energy resolution of ≈3% at 662keV is attainable which is comparable with the highest performance scintillators discovered. In this work, single crystals of KCaI3 with a range of Eu2+ doping between 0 and 5at% substituting for Ca2+ were grown at 22mm diameter and their performance for gamma-ray spectroscopy studied. Comparisons among crystals approximately Ø22mm×22mm (8.4cm3 or ≈0.5in3) provide a more accurate understanding of how scintillation performance changes with Eu doping and increased crystal size. KCaI3 in the undoped form is shown to be a highly efficient intrinsic scintillator with a defect-related emission at 404nm which coexists with the Eu2+ 5d–4f emission in low dopant concentrations and is completely re-absorbed in more heavily doped crystals. For larger crystals, effects from self-absorption due to Eu activation become more evident by a near doubling of decay time for 0.5in3 crystals as the activator is increased from 0.5 to 5.0at% Eu. Comparisons of pulse-height spectra obtained for Ø22mm×22mm cylinders with varying Eu concentration suggests best performance is achieved using lower Eu additions closer to 0.5–1.0at%. Using a modified crystal packaging featuring an offset reflector geometry, 0.5in3 crystals of KCaI3:Eu can attain under 4% energy resolution at 662keV.