2. Introduction
• Luminescence
• Fluorescence
• Fluorophore
• Fluorimetry
• Flurometric analysis
• Fluorescence occurs immediately after the
absorption of light and stops as soon as the
incident light is cut off.
• Phosphorescence
• Phosphorescent substance
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3. Theory
• Singlet state: A molecular electronic state in
which all the electrons are paired.
• In a singlet state molecules are diamagnetic.
• Most of the electrons in ground state are paired.
• When such molecule absorbs uv/visible radiation,
one or more paired electrons reach to the excited
Singlet state/excited triplet state.
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4. Singlet and triplet state
• The electrons spins in excited state achieved by
absorption of radiation may be parallel or
antiparallel.
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5. • When radiation is applied with appropriate
frequency absorption of light by the molecule
cause electrons move from ground state to the
excited first singlet state.
• Once the molecule is in excited state it will try to
move to the original state by several ways.
These are:
Radiationless vibrational deactivation
Fluorescence from the excited singlet state
Quenching of the excited singlet state
Radiationless crossover to the excited triplet
state
Quenching of the triplet state
Phosphorescence form the triplet state
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7. Time relationship Of
Fluorescence Emission
• There is considerable time delay between
Absorption of light energy
Return to the excited state
Emission of the fluorescence
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8. Factors affecting fluorescence
and phosphorescence
• Nature of molecule:
Having conjugated double bonds.
• Temperature/viscosity:
Increase in temperature cause decrease in fluorescence.
Temperature increase viscosity which in turn decrease
fluorescent intensity.
Increase in colloision frequency between molecules will
increase probability of colloisional deactivation and
vibrational relaxation( Colloisional quenching).
Temperature of the reaction must be regulated within +/-
0.1 degree centigrade.
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9. • pH
In the molecules containing acidic or basic
functional groups the change in the medium cause
change in ionization of the functional group.
Eg: aniline shows fluorescence but it does not
show due to formation of anilinium ion in acidic
medium.
Suitable buffer should be used.
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10. • Dissolved oxygen
By direct oxidation of the fluorescent substance to
non-fluorescent substance.
By quenching of fluorescence.
So, useful precaution to check the deaired solution
and compare the result obtained with that from the
oxygen containing solution should be done.
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11. • Solvent
Changes the polarity or H-bonding ability of the
solvent.
Different solvent have different ability to stabilize
the ground and excited states of the fluorescent
molecules.
Solvent viscosity and solvents with heavy atoms
also affects the fluorescence and
phosphorescence.
Ethanol can also cause its own fluorescence.
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12. Concentration effects:
Concentration is proportional to the emitted light energy
absorbed. At maximum concentration fluorescence peaks
and may decrease thereafter.
Light effects:
Monochromatic light is essential for the excitation of
fluoropore because intensity will vary with wavelength.
Very long length of exposure cause decrease in
fluorescence due to photo decomposition.
Increase in intensity of light incident on sample increases
fluorescence intensity.
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13. • Adsorption
Extreme sensitiveness of the method requires very
dilute solutions; 10-100 times weaker than
spectrophotometry.
Adsorption of substance on container wall is
serious problem. E.g. Quinine
Certain quartz glass and plastic materials that
contain uv adsorbants will fluorescence.
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14. • Nature of substituents:
Electron donating group like -NH2, -OH enhance
fluorescence.
Electron withdrawing groups like -COOH, -NO2, -
N=N- and hallides destroy fluorescence.
If a higher atomic number atom is introduced into a
pi-electron system it enhances phosphorescence
and decrease fluorescence.
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15. Applications:
• Determination of vitamin B2 and B1.
• Liquid chromatography
• Organic analysis: quantitative and qualitative
analysis of organic aromatic compounds present
in cigarette smoke, air pollutants, automobile
exhausts, etc.
• Fluorescent indicators: mainly used in acid-base
titration e.g: eosin(colorless to green), quinine
sulphate(blue to violet).
• Pharmaceutical analysis.
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17. References
• Willard H., Merritt L, Settle F, Dean J,
Instrumental methods of Analysis, 7th edition,
New Delhi: CBS publishers and distributors.
• http://www.bertholdtech.com
• Ravi Shankar S, Textbook of Pharmaceutical
Analysis. Fourth edition, Tirunelveli: Rx
Publications
• http://en.wikipedia.org/wiki/Fluorescence
• Gurdeep R Chatwal, Instrumental methods of
Chemical analysis
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