Development of novel plastic scintillators based on polyvinyltoluene for the hybrid j-pet/mr tomograph
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3.1. Scintillation process
The mechanism of scintillation in plastic scintillators is fluorescence. In Fig. 4 the typical energy level diagram in organic scintillators is shown. Figure 4 Scheme of the singlet energy level diagram of organic scintillators [33]. Ionising radiation, incident on the scintillator is partially absorbed and emitted via fluorescence. In this process, the absorbed energy is instantaneously converted to the emitted energy - the decay time in organic scintillators is equal to 10 -10 - 10 -7 s. Fluorescence bands are placed within larger wavelengths in comparison to the incident radiation because emission transition occurs after releasing a part of oscillation energy to the surroundings. Molecules have particular system of energy levels (see Fig. 4): electron, oscillation and rotation. Absorbing the energy, the molecule proceeds to one of the excited states. The excess of the energy can be lost in few ways. The energy of incident radiation is transferred to particular atoms, causing an electron transition from the basic S 0 state to the excited state S 1 or higher, depending on the energy. Non-radiative transitions occur quickly between vibrational states of S 1 (green dashed lines in Fig. 4). Electrons fall from S 1 vibrational states to S 1 basic state is favourable for scintillators. Then, there is an electron transition from S 1 to S 0 state. The excess of the energy is radiated as fluorescence photons within UV or visible wavelengths. 16 For scintillation detectors, the transition from S 1 vibrational states to S 1 base level is favourable. In such decay electrons loose a part of energy. This is a reason of difference between the absorbed and emitted energy. As a consequence, the absorption and emission spectra of scintillating materials are shifted as a function of light wavelength. The difference between the wavelength of the maximum of absorption and the maximum of fluorescence is called Stokes shift. Scintillators are materials with particularly large Stokes shift and therefore the re-absorption of scinitllating light is unlikely [33]. The base of plastic scintillator is polymerizable liquid like styrene or vinyltoluene. This substances scintillate in UV, however the mean free path of produced photons is too short. Therefore scintillation additives are used. Additives (fluors) absorb the primary light from the base and emit it in longer wavelengths. One or more fluors can be used, depending on the desired wavelength of emitted photons. Typical plastic scintillators are ternary systems, consisting of three components: polymeric base, primary fluor and secondary fluor, so called wavelength shifter (WLS) [35]. The scheme of mechanism of the energy transfer in plastic scintillator is shown in Fig. 5. Three components of the plastic scintillators are shown in block scheme in particular sequence, however the scintillator is a homogeneous mixture of these chemical compounds. Yüklə 3,22 Mb. Dostları ilə paylaş:
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