1. IntroductionAccording to our pre

1. Introduction
According to our previous studies, NaI doped by europium in high concentration (40.3%) can be used as an efficient scintillator [1,2]. Detailed investigation of scintillation properties of this com- pound is required for its successful application, including elucidation of the origin of luminescence centers in this crystal. Parfianovich was thefirst to study luminescence centers in europium doped alkali halide crystals (AHC) [3]. A narrow lumi- nescence band peaking at 444 nm was observed in NaI:Eu at To500 K under X ray excitation. Excitation spectrum of this band, as well as comparison with other europium-doped AHC suggests that it was due to emission of divalent europium. The NaI:Eu crystals investigated were grown by the authors from the melt withactivator concentration o0.3 mol%. In order to describe the origin of the activator emission, a model was suggested that the luminescent center could be a cation vacancy complex or dipole (Eu2þvc ). Possibility that such centers can be formed in AHC is quite high since it is the simplest configuration with charge compensation. In other studies [4,5] EPR was used along with luminescent methods to characterize the emission centers. In as-grown samples only one luminescence band at 439 nm was observed, which was identified as the emission of dipole Eu2þvc . In crystals stored for 5 years a more complex spectrum was observed. At least four bands peaking at 415, 439, 461 and 488 nm can be identified. Besides, the emissionspectra could be modified by some thermal treatment. The addi- tional bands were attributed to emission centers formed by EuI2 precipitate and aggregation of dipoles [4,5]. A new hypothesis about the nature of Eu-center in alkali halides was suggested recently based on the study of CsBr:Eu X-ray storage phosphor [6,7]. The analysis of EPR, ENDOR andContents lists available at ScienceDirectjournal homepage: www.elsevier.com/locate/jluminJournal of Luminescenceemission spectroscopy revealed the presence of water/hydrogen radicals in the samples, which allows assuming their impact on the emission centers. In NaI:Eu crystals synthesized by us earlier we observed one of the two luminescence bands (440 nm or 479 nm) depending on the activator concentration [1,2]. It was shown that scintillation prop- erties of NaI:Eu improved with increase of the activator content and gradually reached saturation at relatively high europium con- centrations (Z1.5 10 1% Eu) as found in [1]. Light yield is about 24 103 photon/MeV (60% NaI:Tl) and the best value of energy resolution 6.0% is close to the resolution of NaI:Tl scintillator. Note that in the crystals with the optimal scintillation parameters the long-wavelength luminescence band (470 nm) is dominant, as opposed to the crystals with low europium concentration with luminescence band at 440 nm. Thus, centers II exhibiting long- wavelength luminescence are expected to be responsible for the scintillation process in NaI:Eu crystals. Scintillation crystals are now an important part of many appli- cations, including the detection of