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Nuclear Radiation Detection Scintillators based on ZnSe(Te) crystals.

Published online by Cambridge University Press:  12 July 2011

Volodymyr D. Ryzhikov
Volodymyr D. Ryzhikov*
Affiliation:
Institute for Scintillation Materials of STC “Institute for Single Crystals” NAS of Ukraine, 60 Lenin Ave., Kharkov, 61001, Ukraine
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Abstract

We describe development of semiconductor scintillators (SCS) on the basis of AIIBVI compounds has bridged the gap in a series of “scintillator-photodiode” detectors used in modern multi-channel low-energy devices for visualization of hidden images (tomographs, introscopes). In accordance with the requirements of eventual applications, such SCS materials as ZnSe(Te) show the best matching of intrinsic radiation spectra to photosensitivity spectra of silicon photodiodes (PD) among the materials of similar kind. They are characterized by high radiation and thermal stability of their output parameters, as well as by high conversion efficiency. In this work, a thermodynamic model is described for interaction of isovalent dopants (IVD) with intrinsic point defects of AIIBVI semiconductor structures at different ratios of their charges, a decisive role of IVD is shown in formation of the luminescence centers, kinetics of solid-phase reactions and the role of a gas medium are considered under real preparation conditions of ZnSe(Te) scintillation crystals, and luminescence mechanisms in IVD-doped SCS are discussed.

Keywords

crystaldopantdefects
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1341: Symposium U – Nuclear Radiation Detection Materials , 2011 , mrss11-1341-u04-07
Copyright
Copyright © Materials Research Society 2011

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References

REFERENCES

1. Thomas, D.G. “A review of radiative recombination at isoelectronic donors and acceptors”, J. Phys. Soc. Japan. (1966.) 21. (Suppl.).pp.265271.Google Scholar
2. Pat.35868561971(USA). Radiation detector using isoelectronic trap material. Brown W.L., Height B., Madden T.S. Google Scholar
3. Ryzhikov, V.D., Chaikovskii, E.F. “Development of new scintillation materials on the basis of AIIBVI compounds with an isovalent activator”, Izvestiya AN SSSR, ser. Physics. (1979) 43, No.6 pp. 11501154. (rush.)Google Scholar
4. Kulp, B.A.Displacement of the cadmium atom in single crystal CdS by electron bombardment ”, Phys. Rev. (1962). 125. pp.18651869.Google Scholar
5. Detweiler, R.M., Kulp, B.A. “Annealing of radiation damage in ZnSe”, Phys. Rev. (1966) 146 pp. 513516.Google Scholar
6. Susa, N., Watanabe, H., Wada, M. “Effects of annealing in Cd or S vapour on photoelectric properties of CdS-single crystals”, Jap. J. Appl. Phys. (1976) 15 pp. 23652370.Google Scholar
7. Watkins, J.D. “Lattice defects in II-VI compounds”, Inst. Phys. Cont. Ser. (1977) № 31. Chapter 1. pp.95111.Google Scholar
8. Pat. 77055, 2006(Ukraine), Grinyov B.V., Ryzhikov V.D., Silin V.I. Google Scholar
9. Pat. 74998, 2006 (Ukraine), Starzinskiy N.G., Grinyov B.V., Ryzhikov V.D. Google Scholar
10. Baltramejunas, R., Ryzhikov, V., Gavrushin, V. et al. “Luminescence and nonlinear spectroscopy of recombination center in ZnSe:Te crystals”, J. Luminescence. (1992). 52. pp. 7181.Google Scholar
11. Baltrameunas, R., Gavrushin, V., Ryzhikov, V., Raciukaitis, G.. “Centers of radiative and nonradiative recombination in isoelectronically doped ZnSe:Te crystals”, Phys. B. (1993) 185. pp.245249.Google Scholar
12. Grinyov, B.V., Ryzhikov, V.D., Seminozhenko, V.P. “Scintillation detectors and systems of radiation monitoring on their base” (book). K. : Akademperiodyka (2010), 342p.Google Scholar
13. Ryzhikov, V., Chernikov, V., Galchinetskii, L., Galkin, S., Lisetskaya, E., Opolonin, A., Volkov, V. “The use of semiconductor scintillation crystals AIIBVI in radiation instruments”, Journ. Cryst. Growth. (1999). 197 pp. 655658.Google Scholar
14. Ryzhikov, V., Opolonin, A., Pashko, P., Svisch, V. “Instruments and detectors based of scintillator crystal ZnSe(Te)”, Nuclear Instr. Meth. (2005) A537. pp.424430.Google Scholar
15. Kulakov, M.P., Fadeev, A.V. “About stoichiometry crystals ZnSe were growing from melting”, Izvestia Ac. Sc. USSR, Ser. Inorg. Math. (1981). 17 No.9. pp.15651570.Google Scholar
16. Fistul, V.I. “Distribution isovalent dopant at sublattice multicomponent solid solution AIIBVI ”, Physica and Technique Semiconductors (1983). 17 No.6. pp.11071110 (rush.) Google Scholar
17. Dmitriev Yu, N., Ryzhikov, V.D.About radiation hardness ZnSe(Te) crystals”, J. Atomic Energy (1991). 70 No.2. pp.119121(rush.).Google Scholar
18. Ryzhikov, V., Tamulaitis, G., Starzhinskiy, N. « Luminescence dynamics in ZnSe:Te scintillators », J. Luminescence (2003) 101.pp.4553.Google Scholar
19. Ryzhikov, V., Starzhinskiy, N. “Property and application isovalent doped AIIBVI compound based scintillators”, J. Korea Association for Radiation Protection. (2005) 30. pp.7784.Google Scholar
20. Pat. US6445765B1, 2002 (USA). X-ray detecting apparatus. A. Frank, P. Schall, G. Geus. Google Scholar