Pii: S0969-806X(01)00487-X
Proton stopping power (keV/
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Proton stopping power (keV/
µ m) Luminescence yield (a.u.) 62 MeV-PSI 24 MeV-LNS Linear responce ∆ x=0.1 mm ∆ E Eo Eo- ∆ E 0 4 5 3 7 6 Fig. 2. Luminescence yields as a function of the proton stopping powers. Table 1 Physical characteristics of the polyvinyltoluene scintillator Monomer C 9 H 10 Effective mass number 0.542 Density (g/cm 3 ) 1.032 Maximum light emission (nm) 423 Refraction index 1.58 Attenuation length (cm) 250 Specific heat (J/g 1C) 1.7 Softening temperature (1C) 70 L. Torrisi / Radiation Physics and Chemistry 63 (2002) 89–92 90 The radiation damage effect increases with the stopping power of the incident particle and with the ion dose. The damage produces a decrease in lumines- cence. For 60 MeV proton irradiation (stopping power 1.1 keV/mm), this reduction is about 15% at a dose of 1 kGy. The same decrement is obtained with 300 keV protons (stopping power 65.8 keV/mm) at about 60 kGy dose and with 300 keV argon (stopping power 705 keV/mm) at about 500 kGy dose. Fig. 4 shows a comparison between the emission spectra from PVTas a function of the irradiation dose for 300 keV protons and 300 keV argon beams. All spectra are induced by a 300 nm excitation wavelength. In conclusion, ion irradiation of PVTdrastically produces polymer modifications. Damage appears at doses of the order of 10 12 ions/cm 2 , at which a low hydrogen desorption occurs. It becomes predominant at doses of about 10 13 ions/cm 2 , at which hydrogen and C x H y groups are ejected. At higher values, correspond- ing to MGy absorber doses, the polymer transforms in hydrogenated amorphous carbon and loosens its lumi- nescence characteristics, according to the literature (Torrisi et al., 1997b). References Beddar, A.S., 1994. A new scintillator detector system for the quality assurance of 60 CO and high-energy therapy machines. Phys. Med. Biol. 39, 253–263. Torrisi, L., 1998. Radiation damage in PVT (polyvinyltoluene) induced by energetic ions. Rad. Eff. Def. Solids 145, 271–284. Torrisi, L., 1999. Density enhancement in ion implantated PVT(polyvinyltoluene). Rad. Eff. Def. Solids 147 (4), 241–253. Torrisi, L., Desiderio, A., Foti, G., 2000. High energy proton induced luminescence in F-doped polyvinyltoluene. Nucl. Instrum. Methods Phys. Res. B 166–167, 664–668. Torrisi, L., Cuttone, G., Rovelli, A., Rifuggiato, D., Imbiscuso, R., Raffaele, L., 1997a. Bragg-curve measurements for 24 MeV protons irradiating plastic-water. Phys. Med. XIII (3), 117. Torrisi, L., Cuttone, G., Rovelli, A., Bellia, G., Barone Tonghi, L., Raffaele, L., Licandro, M., 1997b. Energy loss measurements of 27 MeV protons irradiating Fig. 4. Spectra comparison of PVTwavelength emission as a function of the implanted dose for proton and argon ions. Fig. 3. MQS spectra relative to the kinetics of masses 2, 26 and 41, at the beam ON and beam OFF irradiation switches. L. Torrisi / Radiation Physics and Chemistry 63 (2002) 89–92 91 water-equivalent materials. Nucl. Instrum. Methods Phys. Res. B 129, 147. Venkatesan, T., Calcagno, L., Elman, B.S., Foti, G., 1987. Ion beam effects in organic molecular solids and polymers. In: Mazzoldi, P., Arnold, G.W. (Eds.), From Ion Beam Modification of Insulators. Elsevier, Amsterdam, pp. 301 (Chapter 8). Ziegler, J.F., Biersak, J.P., Littmark, U., 1985. In: Ziegler, J.F., Biersak, J.P., Littmark, U. (Eds.), The Stopping and Range of Ions in Solids. Pergamon Press, New York. L. Torrisi / Radiation Physics and Chemistry 63 (2002) 89–92 92 Yüklə 146,57 Kb. Dostları ilə paylaş:
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