BIBLIOGRAPHY 421
[33] McIntyre, R.J., The Distribution of Gains in Uniformly Multiplying
Avalanche Photodiodes: Experimental, IEEE Transactions on Electron
Devices, ED-19(6):713-718, June 1972.
[34] Moses, W.W., Current Trends in Scintillator Detectors and Materials,
Nucl. Instrum. Meth. A, 487, 2002.
[35] Rodnyi, P.A., Physical Processes in Inorganic Scintillators, CRC, 1997.
[36] Ross, H. et al., Liquid Scintillation Counting and Organic Scintillators,
CRC, 1991.
[37] Saleh, M.A. et al., Impact-Ionization and Noise Characteristics of Thin
III-V Avalanche Photodiodes, IEEE Trans. Electron Devices, Vol.48, Dec.
2001.
[38] Stanton, N.R., AMonte Carlo Program for Calculating Neutron De-
tection Efficiencies in Plastic Scintillator, S.N., 1971.
[39] Swank, R., Characterization of Scintillators, Annu. Rev. Nucl. Sci., Vol. 4,
1954.
[40] Taylor, C.J. et al., Response of Some Scintillation Crystals to Charged
Particles, Phys. Rev., Vol.84, No.5, 1951.
[41] Teich, M.C. et al., Excess Noise Factors for Conventional and Super-
lattice Avalanche Photodiodes and Photomultiplier Tubes, IEEE J.
Quantum Electron., Vol.QE-22, 1986.
[42] Trishenkov, M.A., Detection of Low-Level Optical Signals : Photode-
tectors, Focal Plane Arrays and Systems, Springer, 1999.
[43] Weber, M.J., Selected Papers on Phosphors, Light Emitting Diodes,
and Scintillators: Applications of Photoluminescence, Cathodo-
luminescence, Electroluminescence, and Radioluminescence, SPIE-
International Society for Optical Engineering, 1998.