Development of novel plastic scintillators based on polyvinyltoluene for the hybrid j-pet/mr tomograph
Figure 31 The size of spherical free volume as a function of temperature in scintillator based on polystyrene
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- Figure 32 Temperature dependence of ortho-positronium lifetime (τ 3 ) and intensity (I 3 ) in J-PET scintillator based
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Figure 31 The size of spherical free volume as a function of temperature in scintillator based on polystyrene,
containing 2 % of PPO and 0.03 % of 2-(4-styrylphenyl)benzoxazole. Research carried out by PALS method, which are described above are the subject of article [94] by the author of the thesis and collaborators. Because chemical structures of polystyrene and polyvinyltoluene are similar, differing only by the one methyl group connected to aromatic ring in mer, no large differences between PALS spectra of scintillators based on PS and PVT are expected. Samples of J-PET scintillator based on polyvinyltoluene and pure polyvinyltoluene were subjected to PALS measurements. J-PET scintillator beside polyvinyltoluene consists of 2 % of PPO and 0.05 ‰ of the novel WLS. This constitution is set for the most effective J-PET scintillator. In order to determine the influence of fluorescent additives on the structural transitions in scintillator, a sample of pure polyvinyltoluene was tested as well. Ortho-positronium lifetime (τ 3 ) and intensity (I 3 ) were registered as a function of temperature. Conditions of measurements and analysis of obtained results were carried out in the way which is described previously, in the experiment which results are presented in Figs. 29 - 31. PALS results determined for J-PET scintillator based on polyvinyltoluene and for pure polyvinyltoluene are presented in Fig. 32. 64 Figure 32 Temperature dependence of ortho-positronium lifetime (τ 3 ) and intensity (I 3 ) in J-PET scintillator based on polyvinyltoluene (stars) and pure polyvinyltoluene (dots) . Red stars refer to J-PET scintillator when heating, pink ones, when cooling. Dark blue dots refer to pure polyvinyltoluene when heating, light blue dots, when cooling down. In both: scintillator and polyvinyltoluene intensity of o-Ps production increases with temperature, however values obtained in particular temperatures during heating and cooling are different. Such hysteresis is observed also for J-PET scintillator based on polystyrene (Fig. 29). Three different rates of I 3 growth with increasing temperature are observed, for scintillator: 123 - 305 K, 305 - 360 K, 360 - 423 K and for PVT: 123 - 280 K, 280 - 310 K, 310 - 423 K. Points denoted temperatures growth changes for scintillator are slightly shifted towards larger temperatures in comparison to pure matrix. Considering o-Ps lifetime in both samples, one can notice significant difference. There are three rates of τ 3 growth registered for scintillator: 123 K - 260 K, 260 K - 325 K, 325 K - 423 K and only two for pure polyvinyltoluene: 123 K - 310 K and 310 K - 423 K. Existence of an additional point of τ 3 growth change in the scintillator sample is connected with the presence of the additives. 65 Comparing I 3 and τ 3 spectra of polymeric matrix, points indicating structural changes are placed within the similar temperatures, 305 K and 310 K, respectively. Considering results obtained for the scintillator sample, discrepancy in characteristic temperatures indicated by I 3 and τ 3 can be observed. The first one in I 3 is positioned around 260 K, while in τ 3 around 300 K. The second one, in I 3 is placed around 320 K, while in τ 3 within 360 K. It may indicate that I 3 and τ 3 are not equally sensitive for the structural change. It is probable that the change starts in 260 K or further in 320 K for particular polymeric change however in the macromolecule as a whole can be observed only in higher temperatures. Such result can be interpreted as an interval in which the change takes place. The first temperature region is identified as T γ described in the caption of Fig. 29. The second characteristic temperature in which the rate of I 3 growth changes is around 305 K - 310 K for undopped polyvinyltoluene and 320 - 360 K for the scintillator. These are temperatures of glass transitions. Temperatures determined for scintillator and pure matrix differ significantly. Such differences is caused by the dopants which may create regions of local ordering. Glass transition of the polyvinyltoluene - based scintillator (360 K) is similar to the T g of polystyrene - based scintillator (370 K). Tests of I 3 stability within time (as indicated by red arrows) show similar results to the sample of polystyrene-based scintillator. Time constants are shorter in low temperatures: few hours in 123 K and about ten in 173 K. To summarize, results of PALS measurements conducted for polyvinyltoluene - based J-PET scintillator and the pure matrix, are shown in Tab. 10. Yüklə 3,22 Mb. Dostları ilə paylaş:
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