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Spectroscopy for Materials Characterization


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of the processes of absorption (Abs) fluorescence (Fluo), phosphorescence (Phos), and vibrational relaxation (R) are inserted.

      (1.103)equation

      where K 0 is a pre‐exponential factor taking into account entropic‐statistical factors, ΔE is the activation energy of the process, and k is the Boltzmann constant.

      The Jablonski diagram is useful to describe the overall emission features of a system and to schematize the energy levels distribution and their dynamics aspects.

      1.2.5 Excited States Rate Equations

      To go deeper in the emission features, a simplified Jablonski diagram for the transition processes of electrons among vibronic states can be considered, joining the representations reported in Figure 1.4 (bottom) and Figure 1.6. The singlet energy levels S 0 and S 1 are connected by the absorption process and by the radiative fluorescence emission from S 1 with rate images, and the non‐radiative decay with rate images. The T 1 state is populated by the intersystem crossing with rate K ISC, and it is connected to the S 0 state by the phosphorescence emission, with rate images, and by the non‐radiative process with rate images. Under light excitation, it is possible to describe the time‐dependent population of the excited singlet, images, and triplet,images, states by the rate equations [15, 18]:

      where the absorbed light through a sample of thickness L, giving transitions from S 0 to S 1, has been introduced based on Eq. (1.5). It is observed that the emission from the excited states depends on their population; so, it can be stated that for the fluorescence the emitted light is given by

      where the excitation, E exc, and the emission, E em, energies have been introduced together with the temperature dependence and a lineshape f(E em) including the homogeneous and inhomogeneous distributions of levels [18]. Analogously, for phosphorescence, it is found that

      where the lineshape for the triplet to singlet emission of phosphorescence, g(E em), has been inserted. In the stationary state (ss), it is found that

      (1.108)equation

      (1.109)equation