Development of novel plastic scintillators based on polyvinyltoluene for the hybrid j-pet/mr tomograph
Scintillators and scintillation mechanism
Yüklə 3,22 Mb. Pdf görüntüsü
|
|
3. Scintillators and scintillation mechanism
Ionising radiation interacting with matter excites its molecules. When they return to the ground state, photons of the visible or near to visible light spectrum range are produced. This phenomenon is called scintillation. A material in which conversion of excitation energy into light is highly efficient is called scintillator. According to [30] [31], scintillator used in the radiation detectors should be characterized by several properties: transparent at the wavelength of emitted scintillation light high efficiency of light production short light pulses to exclude delayed light emission the amount of light should be proportional to the energy deposited in the material chemical and mechanical stability not prone to radiation damage. It was estimated that one plastic scintillator with dimensions of 0.7 cm x 1.9 cm x 50 cm during one year of utilization in PET scanners would receive a radiation dose about 0.1 kGy. According to article [32], this is more than one order of magnitude less than the dose causing noticable radiation damage in plastic scintillators. Nowadays, scintillation detectors are one of the most popular detectors of radiation. Scintillators are common gamma ray, X-ray, charged and neutral particles detectors. They are utilized in many fields of science and industry. They are the most common detectors used in experiments, regarding the fundamental research in particle and nuclear physics, e.g. to detect particles formed during the process of artificial fusion of atomic nuclei. They are also used as detectors of cosmic rays and in the detectors systems installed at the Large Hadron Collider at the European Centre for Nuclear Research (CERN) in Geneva. Scintillators are widely used in astrophysics to observe emerging stars, the searches for 14 mineral resources and to ensure security at the airports. One can use them on minefields to help in locating the explosive materials without endangering human life. Scintillators are divided into two groups: inorganic and organic. Physics of scintillation mechanism as well as their properties and applications are different. The main difference is that organic scintillators predominantly consist of low atomic number (Z) elements, like carbon and hydrogen, and they have relatively long attenuation length. Inorganic scintillators contains large fraction of elements with high Z (e.g. an effective atomic number of LYSO crystal is equal to 66 u [14]) and attenuation length in that type of scintillators is short. The vast majority of inorganic scintillators are crystals. The mechanism of scintillation is based on electron-hole pairs production in the valence and conduction band during interaction with incident radiation. Light output of inorganic scintillators can be higher (see Table 2) in comparison to organic ones. However they are expensive and the process of crystal growth is difficult to carry out [33]. Organic scintillators are built of chemical substances including phenyl rings. They are found in three types: crystalline, like anthracene or stilbene, liquid, when the scintillator is dissolved in solvent e.g. xylene or toluene and plastic scintillators. Crystalline organic scintillators are expensive and vulnerable. Liquid ones are toxic and its utilization is inconvenient. Because of the volatility, they need to be stored in special containers. The mechanism of luminescence in organic and inorganic crystals differs significantly, what is determined by their intrinsic structure. In organic crystals, molecules are weakly bounded in comparison to inorganic compounds. In such loose arrangement energetic levels are not disturbed by the environment [34]. This thesis concerns plastic scintillators. The scintillation mechanism of organic scintillators will be exemplified for plastic scintillators in the following chapter. |