Proton induced radiation damage studies on plastic scintillators for the Tile calorimeter of the atlas detector
Figure 3-1: Energy level diagram of an organic molecule with π -electron structure, adapted
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Figure 3-1: Energy level diagram of an organic molecule with π -electron structure, adapted
from [1]. The fluorescence process occurs for transitions from the lowest vibrational first excited state (S 10 ) to the ground state, where energy is emitted as a photon of a characteristic wavelength. This process forms the primary mechanism for scintillation in organic plastic scintillators. Fluorescence occurs within a matter of nanoseconds which gives plastic scintillators their fast re sponse capability. Sometimes, transitions called inter-system crossing can occur whereby excited singlet states are converted to triplet states. The lifetime of the T 10 triplet state is longer than that of the S 10 state and so the de-excitation to the ground state from the triplet state takes longer. As a result, a delayed light emission called phosphorescence occurs. The wavelength of the light emitted in phosphorescence is longer than that of light emitted by fluorescence. 16 A final energy loss mechanism that may occur is the process of delayed fluorescence. In this process, molecules in the triplet state may undergo thermal excitation and excite back into the singlet state before undergoing fluorescence to the ground state. [1] Phosphorescence and delayed fluorescence are considers as quenchers of fluorescent light since these three radiative processes can compete with each other. The energy of fluorescent light is generally less than the energy required for absorption because the fluorescence transition can occur to any of the ground state’s vibrational levels and because absorption causes a change to the equilibrium internuclear potential [15]. However, a small amount of overlap may occur between the absorption and emission wavelength ranges resulting in re - absorption of scintillation light. Typical plastic scintillator bases have a very low fluorescent yield and therefore aren’t very transparent to their own scintillation light. Primary fluor dopants are thus added in small concentrations (typically < 3% by weight). Primary fluors are chosen such that their absorption spectra match the emission spectra of the base and generally contain a high quantum yield of the energy transfer transition. Light can be transferred between base and fluor via either radiative re-absorption, or by a non-radiative coulombic interaction called Forster resonance energy transfer. [15] Forster energy transfer is limited by the distance between the interacting states and is therefore more likely to occur with increasing fluor concentrations until a saturation is reached. Light is then emitted by the fluors at higher wavelengths, generally in the UV range of 340-360 nm. Since this wavelength is still below the peak efficiency of common photomultipliers, a secondary fluor is added at concentrations of < 0.1% by weight. The secondary fluor acts as a wavelength shifter and prevents re- absorption of scintillation light by the primary fluor. It also helps to increase the bulk attenuation length of the emitted light. Energy transfer between the primary and secondary fluors occurs via radiative exchange [15]. A schematic of the 17 radiative transfer of energy from polymer base to the primary fluor and secondary fluor is shown in Figure 3-2. Yüklə 8,51 Mb. Dostları ilə paylaş:
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