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Bibliografia e webgrafia
[1] Shobe, J. Electronic Dosimetry Workshop Gaithersburg, MD October 14-16, 1998. Journal of Research of the National Institute of Standards and Technology. 103, 421-424, 1998.
[2] Selici, S. Studio di fattibilità di un sistema di lettura optoelettronico per rivelatori neutronici a
bolle. Elaborato finale per il conseguimento della laurea triennale in Ingegneria della Sicurezza Industriale e Nucleare, Università di Pisa, A.A. 2006/2007.
[3] Portal, G. Dietze, G. Implication of ICRP and ICRU recommendations for neutron dosimetry. Radiation Protection Dosimetry, Vol. 44, pp.165 – 170, 1992.
[4] d’Errico, F. e Curzio, G. Appunti tratti dal corso “Radiazioni Ionizzanti”, a.a. 2005-2006. [5]Selove, W. The interactions of neutron with matter, Nuclear Spectroscopy, Part. A by Fay Ajzenberg-Selove, 1960.
[6]Bollinger, L. M. Techniques of Slow Neutron Spectroscopy, Nuclear Spectroscopy, Part. A by Fay Ajzenberg-Selove, 1960.
[7] Ciucci, I. Radiazioni Ionizzanti, Università degli Studi di Pisa, Dipartimento di Ingegneria Meccanica, Nucleare e della Produzione(2002).
[8] d’Errico, F. Luszik-Bhadra, M. e Lahaye, T. State of the art of electronic personal dosimeters
for neutrons. Nuclear Instruments and Methods in Physics Research, A(505):411–414, 2003. [9]libro tld
[10] Apfel, R.E. The superheated drop detection. Nuclear Instruments and Methods in Physics Reasearch, 162: 603–608, 1979.
[11] d’Errico, F. Radiation dosimetry and spectrometry with superheated emulsions. Nuclear Instruments and Methods in Physics Reasearch, B(184):229–254, 2001.
[12] Delgado, A. Mixed Field Dosimetry, 10th International Congress of The International Radiation Protection Association
[13] d’Errico, F. Alberts, W. G., Dietz, E. Gualdrini, G. Kurkdjian, J., Noccioni, P. e Siebert, B. R. L. Neutron ambient dosimetry with superheated drop (bubble) detectors, Radiation Protection Dosimetry, Vol. 65, pp. 397 – 400, 1996.
[14] d’Errico, F. et al., Electronic neutron personal dosimetry with superheated drop detectors. Radiation Protection Dosimetry, Vol. 96, pp 261-264, 2001.
[15] BDR-IIITM Technical specification, http://www.bubbletech.ca
[16] Vanhavere F.The Bubble Detector for the Determination of Neutron Dose Equivalent¸ Belgian Nuclear research Centre SCK-CEN, NPL, (2003)
[17] Information Note Bubble Detectors Accuracy of Dose Determination, www.bubbletech.ca, (2006)
[18]Luszik-Bhadra M., Boschung M., Coeck M., Curzio G., Derdau D., d’Errico F., Fiechtner A, Kyllönen J.-E., Lacoste V., Lahaye Th., Lindborg L., Molinos C., Muller H., Reginatto M., Schuhmacher H., Tanner R., Vanhavere F. EVIDOS: Optimisation of Individual Monitoring in
mixed Neutron/Photon Fields at Workplaces of the Nuclear Fuel Cycle (2004).
[19]Devine, I.R. Montvila, D. Flynn, D. Brennan, C. and d’Errico, F. An acoustical bubble counter
for superheated drop detectors. Radiation Protection Dosimetry (120):514–517, 2006.
[20] Taylor, C. Weeks, A.R. Pottinger, M.P. e Farrell, P.J.. The use and operational experience of
the Siemens electronic personal dosimeter by BNFL.
[21] Harper, M. J. Bradford, W.B. Nelson, M.E. Investigation of an alternate droplet material
bubble dosimeter. Health Physics Society, 1995.
[22] Apfel, R.E Area/Spectrum Monitor Manual (1989)
[23] Hunsperger, R.G. Integrated optics: theory and technology, Apringer Series in Optical Sciences.
115 [24] Compendium of Neutron Spectra and Detector Reponses for Radiaction Protection Purpose, Supplement for Technical Reports Series n°. 318, International Atomin Energy Agency, Vienna, 2001.
[25] Torrigiani, M. Sviluppo di un dosimetro neutronico personale a lettura optoelettronica Tesi di Laurea Specialistica in Ingegneria Nucleare e della Sicurezza Industriale, Università degli Studi di Pisa, a.a 2006-2007.
[26] Seoul Semiconductor squeezes 240 lumens into "brightest" LED, http://www.engadget.com [27] Kerveno, M. Baumann, P. Nachab, A. Rudolf, G. Pavlik, A. Jericha, E. Jokic, S. Lukic, S. Mihailescu, L.C. Plompen, A. Nolte, R. Reginatto, M. Meulders, J.P. Jeknic, J. Hilaire, S. Koning, A.J. Measurement of (n, xn) cross sections for hybrid systems, http://www.nea.fr.
[28] Bertini, H. W. Low-Energy Inrtanucelar Cascade Calculation, Physical Review, vol. 131 n. 4, 1963.
[29] Metropolis, M. Bivins, R. Storm, M. Miller, J. M. Monte Carlo Calculations on Intranucelar
Cascades. I. Low-Energy Studies, Physical Review, vol. 110 n. 1, 1957.
[30] Ferrari, A. Sala, P. R. The physics of high energy reactions, Workshop on Nuclear Reaction Data and Nuclear Reactors Physics, Design and Safety, ICTP, Trieste, 1996.
[31] MCNPX User’s Manual ver. 2.3.0, Denise B. Pelowitz editor, Los Alamos National Laboratory, (2003)
[32] Mashnik, S. G. Sierk, A. J. CEM2K – Recent development in CEM, Nuclear Theory, 2007. [33] Boudard, A. Cugnon, J. Leray, S. e Volant, C. Intranuclear cascade model for a
