1. SEMINAR ON
PRESENTED BY
MR. NITIN P. KANWALE
M.PHARM. 1ST SEM.
M.V.P. Samaj’s college of
Pharmacy Nashik-2
GUIDED BY
DR.D.V.DERLE
Principal of M.V.P. Samaj’s
college of pharmacy,
Nashik-2
UV-VISIBLE SPECTROSCOPY
NDMVP SAMAJ’S COLLEGE OF PHARMACY NASHIK-2
19/11/20141
2. Content
Introduction
Principle and Basic concept
Some important terms
Instrumentation
Applications
Conclusion
References
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3. INTRODUCTION
Spectroscopy is a technique that measures the interaction of molecules with
electromagnetic radiation.
Light in the near-ultraviolet (UV) and visible (vis) range of the electromagnetic spectrum
has an energy of about 150– 400 kJ mol.
The energy of the light is used to promote electrons from the ground state to an excited
state.
A spectrum is obtained when the absorption of light is measured as a function of its
frequency or wavelength.
The absorbance of a solute depends linearly on its concentration and therefore absorption
spectroscopy is ideally suited for quantitative measurements.
Spectroscopic measurements are very sensitive and nondestructive, and require only small
amounts of material for analysis
Application of derivative technique of spectrophotometry offers a powerful tool for
quantitative analysis of multi-component mixtures.
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4. Principle and Basic concept
Ultraviolet – visible spectroscopy (λ 200 - 800 nm) studies the changes in electronic
energy levels within the molecule arising due to transfer of electrons from π- or non-
bonding orbital's.
It commonly provides the knowledge about π-electron systems, conjugated unsaturations,
aromatic compounds and conjugated non-bonding electron systems etc
UV- Visible is divided into the ultraviolet (UV, 190-400 nm) and visible (VIS, 400-800
nm) regions. Since the absorption of ultraviolet or visible radiation by a molecule leads
transition among electronic energy levels of the molecule, it is also often called as
electronic spectroscopy.
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5. Nature of Electronic Transitions
The total energy of a molecule is the sum of its electronic, its vibrational energy and its
rotational energy.
Energy absorbed in the UV region produces changes in the electronic energy of the
molecule. As a molecule absorbs energy, an electron is promoted from an occupied
molecular orbital (usually a non-bonding n or bonding π orbital) to an unoccupied
molecular orbital (an anti-bonding π∗ or σorbital) of greater potential energy (figure1).
Fig.1)Relative energies of orbitals most commonly involved in electronic spectroscopy of organic
molecules
increasing order of their energies viz. n→π* < n→σ* < π →π* < σ→π* < σ →σ*
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6. Principles of Absorption Spectroscopy: Beer’s and Lambert’s Law
The greater the number of molecules that absorb light of a given wavelength, the greater the
extent of light absorption and higher the peak intensity in absorption spectrum .
This makes the basis of Beer-Lambert Law which states that the fraction of incident
radiation absorbed is proportional to the number of absorbing molecules in its path .
When the radiation passes through a solution, the amount of light absorbed or transmitted is
an exponential function of the molecular concentration of the solute and also a function of
length of the path of radiation through the sample. Therefore,
Log Io / I = ε c l
Where Io = Intensity of the incident light (or the light intensity passing through a reference
cell)
I = Intensity of light transmitted through the sample solution
c = concentration of the solute in mol l-1
l = path length of the sample in cm
ε = molar absorptivity or the molar extinction coefficient , ε is numerically equal to the
absorbance of a solution of unit molar concentration (c = 1) in a cell of unit length ( l = 1)
and its units are liters. moles-1. cm-1.
The ratio I / Io is known as transmittance T and the logarithm of the inverse ratio Io / I is
known as the absorbance A. Therefore
- Log I / Io = - log T = ε c l
and Log Io / I = A = ε c l
or A = ε c 19/11/20146
7. Spectral Measurements
The UV-Vis spectra are usually measured in very dilute solutions and the most
important criterion in the choice of solvent is that the solvent must be transparent
within the wavelength range being examined.
Table lists some common solvents with their lower wavelength cut off limits. Below
these limits, the solvents show excessive absorbance and should not be used to
determine UV spectrum of a sample.
SR.NO. Solvent Cut off
wavelength(nm)
1 Acetonitrile 190
2 Water 191
3 Cyclohexane 195
4 Methanol 203
5 95% ethanol 304
Of the solvents listed in table , water, 95% ethanol and hexane are the most commonly
used solvents.
For recording the spectrum 1 cm square quartz cell is commonly used. These require
approx. 3 ml of solution.
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8. Solvent Effects
Highly pure, non-polar solvents such as saturated hydrocarbons do not interact with
solute molecules either in the ground or excited state and the absorption spectrum of a
compound in these solvents is similar to the one in a pure gaseous state.
However, polar solvents such as water, alcohols etc. may stabilize or destabilize the
molecular orbital's of a molecule either in the ground state or in excited state and the
spectrum of a compound in these solvents may significantly vary from the one recorded
in a hydrocarbon solvent.
Some important terms
(i) Chromophore: The energy of radiation being absorbed during excitation of electrons
from ground state to excited state primarily depends on the nuclei that hold the electrons
together in a bond.
The group of atoms containing electrons responsible for the absorption is called
chromophore. Most of the simple un-conjugated chromophores give rise to high energy
transitions of little use.
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9. (ii) Auxochrome: The substituents that themselves do not absorb ultraviolet radiations but
their presence shifts the absorption maximum to longer wavelength are called
auxochromes. The substituents like methyl, hydroxyl, alkoxy, halogen, amino group etc. are
some examples of auxochromes.
(iii) Bathochromic Shift or Red shift: A shift of an absorption maximum towards longer
wavelength or lower energy.
(iv) Hypsochromic Shift or Blue Shift: A shift of an absorption maximum towards shorter
wavelength or higher energy.
(v) Hypochromic Effect: An effect that results in decreased absorption intensity.
(vi) Hyper-chromic Effect: An effect that results in increased absorption intensity.
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11. 19/11/201411
A) Radiation source:
I. Tungstan lamp
II. Hydrogen discharge lamp
III. Deuterium lamp
IV. Xenon discharge lamp
V. Mercury acr
B) Monochromators
Essential element : Entrance slit
Dispersing element :prism or grating
Exit slit
C)Detector :
I. Barrier layer cell
II. Photocell
III. Photomultiplier tube
12. Applications
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Application to organic compound
Detection of conjugation
Detection of geometrical isomers
Detection of functional group
Qualitative analysis
Detection of impurities
Quantitative analysis
Chemical kinetics
13. Simultaneous Estimation of multi-component formulation by
UV-Visible spectroscopy
Simultaneous equation is applicable for the estimation of those drugs where the
spectra of drug overlap properly whereas, DS method has been widely used to enhance
the signal and resolve the overlapped peak-signals due to its advantages in
differentiating closely adjacent peaks, and identifying weak peaks obscured by sharp
peaks.
Following are the method use
1. Derivative Spectroscopic Method
2. Simultaneous Equation
3. The Absorption Ratio Method : iso-absorptive Point Method
4. Multi-component Mode Method
5. Area Under Curve Method
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14. 19/11/201414
DS has rapidly gained application in the field of pharmaceutical analysis to overcome the
problem of interference, due to the substances other than analytes, commonly present in
pharmaceutical formulations or for combination of two or more drug substances.
DS has been successfully used as a quality control tool in pharmaceutical analysis for the
simultaneous determination of drugs in multi-component formulations. This technique,
accessible to most laboratories, offers an alternative means of enhancing the sensitivity and
specificity in mixture analysis. The procedure is simple, rapid and does not require any
preliminary separations or treatment of the samples.
During the last few decades, a great interest has been seen in the development of various
novel drug delivery systems. In many of these formulations, surfactants like polysorbates
(Tweens) and co-surfactants like propylene glycol and polyethylene glycol (PEG) are used.
However, as those additives exhibit considerable absorbance at the wavelength of
maximum absorbance of diazepam UV-spectrometry method cannot be used to estimate
the drug accurately in their presence. In this sense, Dastidar and Sa present 1st DS as an
accurate, precise, and simple method in comparison to conventional UV-
spectrophotometry method for the estimation of diazepam in presence of Tween-20 and
propylene glycol.
Derivative Spectroscopic Method
15. Conclusions
UV-visible spectroscopy, a simple, rapid, precise and highly accurate method for
quantitative estimation is in great use now a day. Derivative spectrophotometry is an
analytical technique of great utility for extracting both qualitative and quantitative
information from spectra composed of unresolved bands by calculating and plotting one of
the mathematical derivatives of a spectral curve. Therefore the derivative spectra (first to
fourth-order) of the mixtures were checked to select a suitable spectrum to be used for the
simultaneous determination of the components.
Derivative techniques in spectroscopy often offer a powerful tool for a resolution
enhancement, when signal overlaps or interference exists. Several specific signals were
singled out for the components in the spectra of different derivative orders but the first-order
derivative spectra seemed to be generally the most suitable for analytical aim.
A derivative spectrum shows better resolution of overlapping bands than the fundamental
spectrum and may permit the accurate determination of the λmax of the individual bands.
Secondly, DS discriminates in favor of substances of narrow spectral bandwidth against
broad bandwidth substances. All the amplitudes in the derivative spectrum are proportional
to the concentration of the analyte provided that Beer's law is obeyed by the fundamental
spectrum.
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16. References:
1) Gurdeep R. Chatwal, Sham K. Anand, Instrumental Methods Of Chemical Analysis,
Himalaya Publication, Fifth Edition, Page No.2.149-2.184
2)Douglas A. Skoog, Holler, Nieman, Principles Of Instrumental Analysis, Fifth Edition,
Page No.300-352
3)Frank A. Settle, Editor Handbook Of Instrumental Techniques For Analytical
Chemistry, Person Education, Page No.481-499
4) C. Bosch Ojeda, F. Sanchez Rojas, “Recent Applications In Derivative
Ultraviolet/Visible Absorption Spectrophotometry: 2009–2011’’,
Microchemical Journal 106 (2013) 1–16,
Contents Lists Available At SciverseSciencedirect.
Journal Homepage: Www.Elsevier.Com/Locate/Microc.
5) Franz-XaverSchmid, “Biological Macromolecules: UV-Visible Spectrophotometry’’
ENCYCLOPEDIA OF LIFE SCIENCES / & 2001 Macmillan Publishers Ltd, Nature
Publishing Group / Www.Els.Net.
6)Jasmine Chaudhary, Akash Jain, Vipin Saini, “Simultaneous Estimation Of Multi-
component Formulations By UV-Visible Spectroscopy,’’ International Research Journal
Of Pharmacy,
Available Online Www.Irjponline.Com.
7) Www.Wikipedia.Com Accessed On 2/11/2014; 06:30 PM
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