| 1. |
Ryzhikov V. D. 1D- and 2D-matrices scintillation elements on the crystals base ZnSe(Te), CdWO4, CsI(Tl), Bi3Ge4O12 // Functional Materials. - 2004. - 11, № 1.
|
| 2. |
Pogorelova N. V. 2,5-Diaryloxazoles and 2,5-diaryl-1,3,4-oxadiazoles as luminescent dopants for polyorganosiloxane scintillators // Functional Materials. - 2000. - 7, № 1.
|
| 3. |
Zhmurin P. N. 3-Hydroxyflavone tert-butyl fluorine derivative as activator of plastic scintillators // Functional Materials. - 2021. - 28, № 2.
|
| 4. |
Ding Ya. A liquid scintillator for thermal neutrons detection // Functional Materials. - 2009. - 16, № 1.
|
| 5. |
Tretyak S. O. A measuring complex for control the uniformity of the light output of scintillators // Functional Materials. - 2018. - 25, № 4.
|
| 6. |
Ryzhikov V. Absolute light yield of ZnSe(Te) and ZnSe(Te,O) scintillators // Functional Materials. - 2002. - 9, № 1.
|
| 7. |
Gektin A. Advanced approach to estimation scintillator energy resolution // Functional Materials. - 2020. - 27, № 1.
|
| 8. |
Gektin A. V. Advanced method of scintillator energy resolution test // Functional Materials. - 2019. - 26, № 1.
|
| 9. |
Burachas S. F. Advanced scintillation single crystals based on complex oxides with large atomic number // Semiconductor Physics, Quantum Electronics and Optoelectronics. - 2000. - 3, № 2.
|
| 10. |
Zorenko Yu. Application of scintillators based on single-crystalline Lu3Al5 O12 : Ce3+ films for radiation monitoring in biology and medicine // Semiconductor Physics, Quantum Electronics and Optoelectronics. - 2000. - 3, № 2.
|
| 11. |
Nemchenok I. B. Boron-loaded liquid scintillator // Functional Materials. - 2013. - 20, № 3.
|
| 12. |
Vasetsky S. I. Characteristics changes of unsealed NaI(Tl) detector under atmospheric moisture effect // Functional Materials. - 1998. - 5, № 4.
|
| 13. |
Karavaeva N. L. Combined composite scintillation detector for separate measurements of fast and thermal neutrons // Functional Materials. - 2010. - 17, № 4.
|
| 14. |
Zaslavsky B. G. Comparative analysis of thermal conditions at growing of large CsI(Tl) scintillation single crystals by automated pulling from the melt using cylindrical and conical crucibles // Functional Materials. - 1999. - 6, № 4.
|
| 15. |
Kilimchuk I. V. Comparison of different rough surface models for computer simulation of light collection in a scintillator/light guide system // Functional Materials. - 2007. - 14, № 4.
|
| 16. |
Litichevskyi V. Composite scintillation panels and elements based on fine-grained granules of crushed crystals // Functional Materials. - 2013. - 20, № 2.
|
| 17. |
Karavaeva N. L. Composite scintillators for a wide range of problems in detection of ionizing radiation // Functional Materials. - 2014. - 21, № 4.
|
| 18. |
Onyshchenko G. Counting efficiency and neutron/gamma ratio for KDP: TL+ and UPS-923A scintillators in a single photon detection mode // East Europ. J. of Physics. - 2020. - № 3.
|
| 19. |
Grinyov B. V. Crystal shape variation as a way to improve the axial directionality of scintillation gamma detectors // Functional materials. - 2002. - 9, № 3.
|
| 20. |
Khanbekov N. D. Data analysis of the internal background measurements of <$E bold roman {nothing sup 40 Ca sup 100 MoO sub 4}> scintillation crystals // Ядер. фізика та енергетика. - 2013. - 14, № 2.
|
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