![]() Phys Stat Sol (a) 178:595–620īecker J, Belski AN, Boutett D et al (1993) Relaxation of electronic excitations in wide bandgup insulators. Nikl M (2000) Wide band gap scintillation materials: progress in the technology and material understanding. Wojtowicz AJ, Berman E, Lempicki A (1992) Stoichiometric cerium compounds as scintillators, II CeP5O14. Rodnyi PA (1997) Physical processes in inorganic scintillators. Lempicki A, Wojtowicz AJ, Berman E (1993) Fundamental limits of scintillator performance. Van Roosbroeck W (1965) Theory of the yield and Fano factor of electron-hole pairs generated in semiconductors by high-ehergy particles. Robbins DJ (1980) On predicting of maximum efficiency of phosphor systems excited by ionizing radiation. Lempici A (1995) The physics of inorganic scintillators. Rodnyi P, Dorenbos P, van Eijk CWE (1995) Energy loss in inorganic scintillators. Khruchinski A, Korzhik M, Lecoq P (2002) The phenomenon of scintillation in solids. Moscow State University, Moscow, pp 43–52 In: Mikhailin VV (ed) Proceedings of the fifth international conference on inorganic scintillators and their applications, SCINT99. Vasiliev A (2000) Relaxation of hot electronic excitations in scintillators:account for scattering, track effects, complicated electronic structure. Klienknecht K (1987) Detektoren fur Teilchenstrahlung. Verlag G.Braun, KarlsruheĬherenkov PA (1934) A visible radiation of pure liquids under γ-radiation. Prokhorov AM (ed) (1998) (In Russian) Physics Encyclopedia Big Russian Encyclopedia 5:41įünfer E, Neuert H (1959) Zalhrohre und szcintillationszzälher. Hofstadter R (1949) The detection of gamma-rays with thallium-activated sodium iodide crystals. Proc Phys Soc (London) Letters to the Editor 80:474–475 Schorr MG, Torney FL (1950) Solid non-crystalline scintillation phosphors. Kallmann H, Furst M (1951) High energy induced fluorescence in organic liquid solutions (energy transport in liquids). Kallmann H, Furst M (1951) Fluorescence of solutions bombarded with high energy radiation (energy transport in liquids). Kallmann H, Furst M (1950) Fluorescence of solutions bombarded with high energy radiation (energy transport in liquids). Proc Phys Soc (London) Letters to the Editor 78:621–622 Kallmann H (1950) Scintillation counting with solutions. Phys Rev 73:1259–1260īell PR (1948) The use of anthrance as a scintillation counter. Phys Rev 75:623–626Ĭollins GB, Hoyt RC (1948) Detection of beta-rays by scintillations. Kallmann H (1949) Quantitative measurements with scintillation counters. Moon RJ (1948) Inorganic crystals for the detection of high energy particles and quanta. Phys Rev 72:528Ĭoltman JW, Marshall FH (1947) Some characteristics of the photo-multiplier radiation detector. Marshall FH, Coltman JW (1947) The photo-multiplier radiation detector. This process is experimental and the keywords may be updated as the learning algorithm improves.īroser VI, Kallmann H (1947) Uber die Anregung von Leuchtstoffen durch schnelle Korpuskularteilchen I. These keywords were added by machine and not by the authors. This chapter is concluded with a list of the scintillation materials developed so far and of their most important properties. Several approaches to classify scintillation materials are discussed. It is shown that these two ions are good activators with a bright and fast scintillation in many compounds. As an example the electron energy level structure of Ce 3+ and Pr 3+ is described. A description is given of the most important activators with a discussion about the conditions for the activator to be efficient in a host matrix. After a survey of scintillation mechanisms it is shown that several self-activated scintillators show better scintillation properties when they are doped with appropriate ions. Definitions are then given of the parameters related to the physical process of light production in the medium, and not dependant on the shape, surface state and optical quality of the scintillator block. It starts with an historical brief and describes the sequence of the processes leading to scintillation in a dielectric medium. This chapter introduces the basic definitions and gives the minimum necessary information about the phenomenon of scintillation and the mechanisms which have to be taken into account for the development of scintillation materials.
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