Ultraviolet and Visible Spectroscopy PDF

Summary

This document provides a lecture on ultraviolet and visible spectroscopy, covering its principles, applications, and relevant terminologies. It delves into the interaction of molecules with electromagnetic energy and the use of different spectroscopic methods, including ultraviolet-visible (UV-Vis) spectroscopy, infrared (IR) spectroscopy, and nuclear magnetic resonance (NMR) spectroscopy. It includes details about various chromophores and auxochromes and how they affect the absorption of light.

Full Transcript

Ultraviolet and visible
spectroscopy
 Learning outcomes
At the end of this session students shall be able to

1. Explain basic principles of UV-Visible spectroscopy

2. Explain relevant terms of UV-Visible spectroscopy

3. Explain working principle, taking spectra

4. Describe the outline of UV spectroscopy device
 Spectroscopy
Spectroscopy is an analytical method that involve the
interaction of molecules with electromagnetic energy
Example of spectroscopic techniques are: Infrared (IR),
ultraviolet-visible (UV-Vis) and nuclear magnetic
resonance (NMR) spectroscopy.
 Electromagnetic radiation (EMR)
Electromagnetic radiation is a radiation consisted of discrete packages of energy called
photons.
The packages make the electromagnetic spectrum which is arbitrarily divided into
regions
 EMR
Electromagnetic radiation has dual wave-particle behavior.
As a wave it has:
Wavelength, λ, = the distance btw successive trough or crest.
Frequency, ν, = the number of cycles per second.
The amplitude = the height of a wave, measured from midpoint to
peak.
The velocity,
The Energy,
 UV - Visible radiation
The UV radiation extends from 10 – 400 nm
200 – 400 nm is near UV region
below 200 nm is far UV region
The visible radiation extends from 400–800 nm

Note: Far UV spectroscopy is studied under vacuum condition
 Principle of UV-Vis spectroscopy
In UV-Vis radiation, a molecule absorb energy that promote an electron from a lower-energy orbital to a
higher-energy one.
E.g. In 1,3-butadiene absorption of UV radiation promotes an e- from HOMO to LUMO. (from ) (energy =
217 nm)

HOMO = highest occupied molecular orbital
LUMO = lowest unoccupied molecular orbital
 Possible electronic transitions

The UV-Vis spectroscopy is applicable to molecules
capable of transitions (λ >200 nm) – Molecules
containing conjugated  systems and lone pair of e-s.
 The UV spectrum

A UV spectrum is a chart
that plots wavelength versus
absorbance (A)
UV/Vis absorption bands
are broader because the
transition btw electronic
energy levels also
include a transition
between vibrational
energy levels.
Thus closely spaced
absorption bands merge
together to form a single
broad band.
 Terminologies: chromophore
Chromophore: is the functional group capable of
absorbing UV-Vis radiation
E.g. C=C, C=S, C=O, C=N, NO2, N=O, C≡N
1. Non-conjugated alkenes
2. Non-conjugated C=O
3. Conjugated system
4. Conjugation of C=C and C=O shifts the of both groups
to longer wavelength
 Characteristics of some chromophores
max max max max
Chromophore Chromophore Chromophore Chromophore
(nm) (nm) (nm) (nm)

H2C CH2
171 178 227 255
Ethylene 1,5-hexadiene 1,3-hexadiene
Benzene

O
O O O
C 279 291 290 C OH 273
H3C CH3 H3C H
Acetone Crotonaldehyde Benzoic acid
Cyclohexanone

O
C C C OH 273 292
H H
(CH2)3NHMe
Cinnamic acid
Protriptyline
 Terminologies: Auxochrome
Auxochrome: is the functional group attached to
chromophore that alters the wavelength or intensity of
absorption
(e.g. –OH, -NH2, -CH3, -OCH3 )
Auxochrome modifies the ability of the chromophore to
absorb light
OH NH2

Benzene Phenol Aniline
max= 255 nm max= 270 nm max= 280 nm
 Absorption and intensity shifts
Shift Description Example
Bathochromic effect Shifts to longer wavelength Benzene λmax = 255 nm
(Red shift) due to presence of an Phenol λmax = 270 nm
auxochrome or change of p-nitrophenol (PNP) λmax = 255 nm
solvent. PNP in alkaline medium λmax = 265 nm
Hypsochromic effect Shift to shorter wavelength Aniline λmax = 280 nm
(Blue shift) due to presence of groups Aniline in acid medium λmax = 265 nm
that causes removal of
conjugation or by the (loses conjugation)
change of solvent
Hyperchromic effect An increase in absorption Pyridine log ϵ = 3.3
2-picoline log ϵ = 3.4

Hypochromic effect A decrease in absorption Naphthalene log ε = 4.28
2-methyl naphthalene log ε = 4.01
 Absorption and intensity shifts
Hyperchromic shift

Blue Red
Absorbance ( A )

shift shift

Hypochromic shift

λmax
Waveleng
 Absorbance (A)/transmittance (T)
When a solution of a sample is irradiated by EMR of intensity
I0

where I = transmitted energy and I = incident energy
0

Absorbance

But

A
 Beer–Lambert Law
When a monochromatic radiation is passed through a solution, the
decrease in the intensity of radiation with thickness of the solution is
directly proportional to the intensity of the incident light and
concentration of the solution
gives
Converting from ln to log, and substituting for absorbance,
gives A = αbC
where α is the analyte’s absorptivity with units of cm–1 conc–1.
When concentration is expressed using molarity, the
absorptivity is replaced by the molar absorptivity, ε (with
units of cm–1 M–1)
Thus A = εbC (Beer’s Law)
The ε give the probability that the analyte will absorb a
photon of given energy. Thus, the value for ε depend on the
wavelength of electromagnetic radiation.
 Beer’s Law - Quantitative Applications
If ε and b are constants The Beer’s law
gives
A≈C
Thus, solution of different
concentrations of an analyte should
give a linear calibration curve with no
intercept.
Accordingly, the calibration curve can
be used to determine unknown
concentration in sample of the same
analyte
 Beer’s law for pharmaceutical products
To express concentrations in grams or milligrams the Beer’s law is
written as follows for pharmaceutical products.

where,
A = absorbance
A (1%, 1 cm) = absorbance of a 1% w/v solution in a 1 cm cell,
l = pathlength in cm
c = the concentration of the sample in g/100 ml
(in g/ml) if l = 1cm
 Examples
What are the concentrations of the following solutions of drugs in
g/100 ml and mg/100 ml?
i. Carbimazole, A (1%, 1 cm) value = 557 at 291 nm, measured
absorbance = 0.557 at 291 nm.
ii. Hydrocortisone sodium phosphate, A (1%, 1 cm) value= 333 at 248
nm, measured Absorbance = 0.666 at 248 nm.
iii. Isoprenaline, A (1%, 1 cm) value = 100 at 280 nm, measured
absorbance, = 0.500 at 280 nm
Answers:
(i) Carbimazole 0.001 g/100 ml, 1 mg/100 ml
(ii) Hydrocortisone sodium phosphate 0.002 g/100 ml, 2 mg/100 ml
(iii) Isoprenaline 0.005 g/100 ml, 5 mg/100 ml.
 A spectrophotometer

Component Description
Light Source lamps emitting UV-visible light. e.g. tungsten, deuterium and
mercury lamp.
Monochromator isolate individual wavelengths of light. e.g. prisms and Diffraction
gratings
Sample cell glass or Quartz (glass not suitable for UV region)
Photodetectors convert transmitted radiation into electrical energy
Analog to-digital (A/D) converters the signal to a voltage and digital.
 Photodetectors

Incident light

Photocell on illumination cathode
generates current that is Photodiode array (PDA) use
proportional to incident pn-junction diode. less
Photomultiplier tube (PMT) detects
radiation. sensitive than PMT, but
and amplifies radiant energy by
Disadvantage: no excellent linearity, speed,
dynodes, that produce a successively
amplification. temperature and small size give them
higher positive voltage. PM T is >
sensitive , nonlinear at very advantage
200 times more sensitive than the
low and very high
phototube.
illumination.
 Double beam spectrophotometer
Double-beam spectrophotometers permit automatic
correction of sample and reference absorbance. The system
performs continuous zeroing electronically
Qualitative and Quantitative application
 Examples of the Molecular UV/Vis Analysis of
Clinical Samples

Analyte Method λ(nm)

total serum react with NaOH and Cu2+; forms blue-violet 540
protein complex
serum cholesterol react with Fe3+ in presence of isopropanol, acetic 540
acid, and H2SO4; forms blue-violet complex
uric acid react with phosphotungstic acid; forms tungsten 710
blue
serum extract into CHCl3 to isolate from interferents and 260
barbiturates then extract into 0.45 M NaOH
glucose react with o-toludine at 100oC; forms blue-green 630
complex
protein-bound decompose protein to release iodide, which 420
iodine catalyzes redox reaction between Ce3+ and As3+;
forms yellow colored Ce4+
 Steroidal androgens and corticosteroids
The chromophores of steroidal androgens and corticosteroids is enone.
All show absorbance maxima of similar intensity, at around 240 nm.
Shapes of the spectra may be different and can be used in qualitative identity
tests.
Steroid Mwt λmax A (1%, 1 cm)

Hydrocortisone 362.5 240 435
Betamethasone 392.5 240 390
Clobetasol butyrate 479.0 236 330
Betamethasone
516.4 241 296
sodium phosphate
 Ephedrine: the benzoid chromophore
Ephedrine and other molecules
having simple benzene ring as
chromophore absorb at λmax = 260
nm [A (1%, 1 cm) = 12].
Like benzene its most intense
absorption maximum is below 200
nm.
its vibrational fine structure is
preserved because the
chromophore does not interact Similar drugs include:
strongly with the solvent. diphenhydramine, amphetamine,
ibuprofen and dextropropoxyphene.
 Ketoprofen: extended benzene chromophore

The chromophore in
Ketoprofen is the extended
benzoid system
λmax = 262 nm, [A (1%, 1 cm) =
647, a bathochromic shift from
the strong absorbance band in
benzene (λmax = 204 nm).
Similar drugs include:
cyproheptadine,
dimethindine, protriptyline,
zimeldine.
 Procaine: amino group auxochrome
In procaine, the benzene
chromophore is extended by the
C=O and has an amino auxochrome
all producing bathochromic shift
under basic conditions, λmax = 279
nm with an A (1%, 1 cm) = 100.
Under acidic conditions, λmax = 270
nm with an A (1%, 1 cm) = 1000 (a
hyperchromic shift).
Similar drugs include: procainamide
and proxymetacaine.
 Phenylephrine: hydroxyl group auxochrome
The hydroxyl auxochrome interact with the chromophore under
both acidic and alkaline conditions.
Under acidic conditions λmax = 273 nm, A (1%, 1 cm) = 110
Under alkaline conditions λmax = 292 nm, A (1%, 1 cm) = 182
(bathochromic and hyperchromic shift)
 Quantitative analysis
Assay examples : Furosemide (frusemide) in tablet form
Measured powder of furosemide (frusemide) is shaken with ~ 300 ml of 0.1 M NaOH to extract
the acidic furosemide (frusemide).
The extract is then made up to 500 ml with 0.1 M NaOH.
A portion of the extract is filtered and 5 ml of the filtrate is made up to 250 ml with 0.1 M NaOH.
The absorbance of the diluted extract is measured at 271 nm. A (1%, 1 cm) = 580 at 271 nm in basic
solution.
From the data below calculate the % of stated content in a sample of furosemide (frusemide)
tablets:
– Stated content per tablet: 40 mg of furosemide (frusemide)
– Weight of 20 tablets: 1.656 g
– Weight of tablet powder taken for assay: 0.5195 g
– Absorbance reading: 0.596.