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Fluorescence. Topics. Definition Theory’s Factor’s Instrumentation Applications. Luminescence. Emission of previously absorbed radiation. Types : Luminescence is two types 1. Florescence 2.Phosphorescence. Fluorescence.
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Topics • Definition • Theory’s • Factor’s • Instrumentation • Applications
Luminescence • Emission of previously absorbed radiation
Types : • Luminescence is two types • 1. Florescence • 2.Phosphorescence
Fluorescence • When a beam of light is incident on certain substances, they emmit visible light or radiations. • ( The substance is fluorescent substance. Measurement is called as fluorimetry. )
Phosphorescence • When a beam of light is incident on certain substances, they emit radiations continuously even after the incident light is cut off . • (The substance is phosphorescent. Measurement of radiations is Phosphorimetry. )
Types of fluorescence • 1. Based upon the wave length of emitted radiation when compared to absorbed radiation • - Stokes's fluorescence • - Anti- Stokes's fluorescence • - Resonance fluorescence
2. Based upon the phenomenon • - Sensitized fluorescence • - Direct line fluorescence • - Stepwise fluorescence • - Thermally assisted fluorescence
Theory • 1.Singlet and triplet states • 2.Excited-state state process in molecules • 3.Relation between fluorescence intensity and concentration • 4.Factors affecting fluorescence
Singlet and triplet states • A molecular electronic state in which all of the electron spins are paired is called a singlet state. (spine state) • If ‘no’ un pair electrons are present (n=0), there is only n+1 or 0+1 spin state. Such state is called a singlet state. Similarly, systems having 1,2,3,4…… unpaired electrons refer to doublet, triplet, quartet etc. state respectively
Excited –state processes in molecules • 1.Collisional deactivation • 2.Fluorescence • 3.phosphorescence
v7 v7 v5 v5 v3 v3 v0 v0 v5 v3 v0 processes in molecules Absorption Collisional deactivation Fluorescence Phosphorescence Intersystem crossing Vibrational relaxation S1 T v4 v2 S0
Relation between intensity of fluorescence and concentration • We know that “less number of molecules absorb lesser radiation and so emit lesser radiation”. • “similarly more number of molecules absorb more radiation”.
Fluorescence intensity=Q x Ia • Ia -intensity of absorbed light • Q – fluorescence efficiency • Q= fluorescence quantaemitted • EMR quanta absorbed
Since Emission is proportional to Absorption. • Ia = Io- It • I0 = Intensity of incident light • It = Intensity of transmitted light • It = I0 e –act • Ia = I0 – I0 e –act • Ia = I0 – (1-e –act) • Ia = I0(1-(1-act)) because e –act =1-act
Ia = Io (1-1+act) • Ia = I0 x act • F.I = Q x Ia • F.I = QI0act • Q = constant for a particular substance • I0 = constant for an instrument • a = molecular extinction coefficient • T = path length • C = concentration
Fluorescence intensity is proportional to the concentration of the substance. • If the concentration is high it does not fallow due to quenching effect. Low con High con % intensity % intensity concentration concentration
Quenching • Quenching is the decrease in fluorescence intensity • Types : • Self or concentration quenching • Chemical quenching(ph,o2,halides,heavy metals) • Static quenching • Collisional quenching
Factors • Nature of molecules • Nature of substitutent’s • Effect of concentration • Light • Methods of illumination • Oxygen • Photodecomposition • Temperature and viscosity • Adsorption
Nature of molecules • Compounds which absorb U.V and VIS radiations shows the fluorescence. • Molecules having conjugated double bond are suitable. • Aliphatic and Saturated cyclic organic compounds are not suitable.
Nature of substitutents • Electron donating groups like –NH2, -OH enhance the fluorescence. some of the groups like -SO3H,-NH4 and Alkyl groups not effect Phosphorescence and Fluorescence. • Electron withdrawing groups like -COOH, -NO2,-N=N- and Halides decrease or even destroy the Fluorescence
Effect of concentration • Fluorescence αConcentration • (only for small values ) • Concentration should low to get good results weak strong
Light: Monochromatic light is essential. • Methods of illumination :Right angle method is only used ,another method is frontal method. • Oxygen :It shows two effects • - Oxidation of fluorescent substance in to non-fluorescence substance. • - Quenching the fluorescence. • Photodecomposition : Radiation passing through the solutions is weak adequate for the measuring.
Photodecomposition: Radiation passing through the solution is weak adequate for the measuring • Temperature and viscosity : variations in temperature and viscosity will cause variations in the frequency • Adsorption:For the fluorimetry we need 10 – 100 weaker solution than the spectrophotometry
Instruments • Source : mercury vapor lamp, xenon arc lamp, tungsten lamp. • Filters and monochromators • primary filter • secondary filter • Sample cell • Detectors
Instruments • Source :Mercury vapor lamp, Xenon arc lamp, Tungsten lamp. • Filters and monochromators • primary filter • secondary filter • Sample cell • Detector’s
Single beam fluorimeter cuvette Low pass filter High pass filter Photomultiplier tube Tungsten source
Double beam fluorimeter Sample Solution Secondary Filter Primary Filter Photo Multiplier Tube Lamp Primary Filter Secondary Filter Reference or blank
Applications • Inorganic chemistry • Organic chemistry • Biological • Food products • Pharmaceutical • Clinical • Natural products
Notes • Fluorescence- relaxation through the emission of a photon • Generally occurs on the ms-ns timescale. • Phosphorescence is the emission of a photon from a excited triplet state • Phosphorescence is an extremely rare property
Notes • Absorption occurs on the 10-15 seconds • Relaxation from the ground state occurs through the fastest available process • Most molecules do not fluoresce because the excited vibrational states of S0 overlap with the S1 state and relaxation can take place rapidly by vibrational relaxation • Generally on the picoseconds timescale