[1] Blasse, G., Grabmaier, B. C.: Luminescent Materials. Springer-Verlag, Berlin 1994.
[2] Rodnyi, P. A.: Physical Processes in Inorganic Scintillators. CRC Press, New York 1997.
[3] Nikl, M.: WIDE BAND GAP SCINTILLATION MATERIALS. Progress in the technology and material understanding. Phys. Stat. Sol. (a) 178 (2000), 595–620.
[4] Globus, M. E., Grinyev, B. V.: Inorganic Scintillators. Akta, Kharkiv, Ukrajina 2000.
[5] Nikl, M., Mihokova, E., Vedda, A., Shimamura, K., Fukuda, T.: Oxide and fluoride based materials for scintillator applications. J. Ceramic Proc. Res. 2 (2001), 16–20.
[6]
Funkcionalnyje materialy dlja nauki i techniki. Ed. V. P. Seminozhenko. Institut monokristalov, Kharkov, Ukraina 2001.
[7] Auffray, E.: Extensive studies on CeF$_3$ crystals, a good candidate for electromagnetic calorimetry at future accelerators. Nucl. Instr. Meth. Phys. Research A383 (1996), 367–390.
[8] Annenkov, A. A., Korzhik, M. V., Lecoq, P.: Lead tungstate scintillation material. Nucl. Instr. Meth. Phys. Research A490 (2002), 30–50.
[9]
NATO Science For Peace Project No. 973510 “New Scintillator Materials For Scientific, Medical And Industrial Applications”. Další informace viz
http://www.fzu.cz/~nikl/NATO/
[10] Birch, D. J. S., Imhof, R. E.: J. Phys. E10 (1977), 1044.
[11]
Firma IBH Scotland je jednou z nejlepších firem v oblasti produktů pro měření časověr̄ozlišené luminiscenční spektroskopie. Viz
http://www.ibh.co.uk/
[12] Baccaro, S., Boháček, P., Borgia, B., Cecilia, A., Dafinei, I., Diemoz, M., Ishii, M., Jarolimek, O., Kobayashi, M., Martini, M., Montecchi, M., Nikl, M., Nitsch, K., Usuki, Y., Vedda, A.: Influence of La-doping on radiation hardness and thermoluminescence characteristics of PbWO4. Phys. Stat. Sol. (a) 160 (1997), R5-R7.
[13] Laguta, V. V., Martini, M., Vedda, A., Nikl, M., Mihoková, E., Boháček, P., Rosa, J., Hofstatter, A., Meyer, B. K., Usuki, Y.: Photoinduced Pb$^+$ center in PbWO$_4$: Electron Spin Resonance and Thermally Stimulated Luminescence study. Phys. Rev. B64 (2001), 165102–8.