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Electronic Spectroscopy Hitachi-HiTec. Electronic Excitation Model A ~ X ~  Excitation (Absorption) Radiationless decay (vibrational relaxation)  Fluorescence.

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Presentation on theme: "Electronic Spectroscopy Hitachi-HiTec. Electronic Excitation Model A ~ X ~  Excitation (Absorption) Radiationless decay (vibrational relaxation)  Fluorescence."— Presentation transcript:

1 Electronic Spectroscopy Hitachi-HiTec

2 Electronic Excitation Model A ~ X ~  Excitation (Absorption) Radiationless decay (vibrational relaxation)  Fluorescence (Fast radiative decay) Internal conversion (Slowish non-radiative decay)

3 Electronic Excitation Model A ~ X ~ a ~  Excitation Intersystem crossing Radiationless decay (vibrational relaxation) Phosphorescence (Slow radiative decay)  Intersystem crossing (Slow non-radiative decay)

4 Franck-Condon Principle The intensities of observed peaks in UV-Vis spectra depend on the overlap between the initial and final vibronic states A ~ X ~ A ~ X ~ Good Overlap-Strong Peaks Eh Overlap-Weak Peaks

5 Fluorescence Spectra Hitachi-HiTec A Plasma Display Panel Fluorescence Spectrum Excite mostly in the UV

6 Fluorescence Spectra A neat fluorescence spectrum tool for assorted fluoro-cores: http://www.bdbiosciences.com/ca/research/multicolor/spectrum_viewer/index.jsp

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