SCH 2450 - Molecular Spectroscopy (Notes) PDF

Summary

Lecture notes on Molecular Spectroscopy. The document contains course objectives, a course description, learning outcomes and details of the course contents. The document also includes references and course materials.

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SCH 2450: MOLECULAR SPECTROSCOPY
Course objectives
- Demonstrate knowledge on the various molecular spectroscopic techniques
- Demonstrate competence in the use of molecular spectroscopic techniques in analysis of real
samples

Course description
Absorption of electromagnetic radiation by molecules, Molecular electronic energy levels,
vibrational energy levels, Raman effects, Lasers. Ultraviolet and visible absorption methods of
analysis, Instrumentation. Quantitative methods, differential, difference and derivative
spectroscopy, Turbidimetry and Nephelometry. Fluorescence, Phosphorescence and
chemiluminescence spectroscopy, instrumentation and applications. Practicals to include
applications of the various techniques.

Learning outcomes
At the end of this course Learner should be able to:
- Describe the various molecular energy levels
- Explain the principles of UV-Vis, Raman, turbidimetry, nephelometry, fluorescence,
phosphorescence and chemiluminescence spectroscopic techniques
- Distinguish between differential, difference and derivative spectroscopy
- Describe the instrumentation behind the various molecular spectroscopic techniques.

Teaching Methodology:

Lectures, Tutorials and practicals

Instructional Materials

Whiteboard/ smart board, white board markers, computer and projector, course notes, Duster

Course assessment

Written CATS 15%, assignments 5%, Practicals 10%, final written examination 70%

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Course Journals

1. Journal of Analytical Sciences, Methods and Instrumentation Published/Hosted by Scientific
Research Publishing. ISSN (printed): 2164-2745. ISSN (electronic): 2164-2753
2. International Journal of Analytical Chemistry ISSN: 1687-8760
3. Journal of Chromatography A, ISSN 0021-9673

Reference Journals

1. International Journal of Analytical Chemistry ISSN: 1687-8760
2. Talanta Imprint: ELSEVIER ISSN: 0039-9140
3. The Annual Review of Analytical Chemistry ISSN: 19361335, 19361327
4. Trends in Analytical Chemistry ISSN: 0165-9936

REFERENCES
1. Kemp W. (1991). Organic spectroscopy, 3rd edition, McMillan. London
2. Williams, D. H., and Fleming, I (1989) Spectroscopic Methods in Organic Chemistry,
4th Edition, McGraw-Hill Book Company
3. Silverstein, R. M., Webmaster, F.X and Kiemle, D.J. (2005) Spectroscopic Identification
of organic compounds. 7th edition. John Wiley

REFERENCES (MAIN)

1. Instrumental Methods of Analysis, Willard, H.H., Merritt, L.L., JR; Dean, J.A. and Settle,
F.A. (JR), CBS Publishers & Distributors, 6th Edition, 1986. 485 Jain Bhawan, BholaNath
Nagar Shahadra Delhi-110032, 1030pp.
2. Modern methods of Chemical Analysis, R.L. Pecsok, L.D. Shields, T. Cairns and I.G.
McWilliam. John Wiley and Sons, Inc.,1976. 573pp.
3. Principles of Instrumental Analysis, Douglas A. Skoog, CBS College Publishing (Saunders
College Publishing), 3rdEdition, 1985.
4. Internet, e.g. Googles (e.g. Wikipedia, etc.)
5. etc.

SCH 2450: MOLECULAR SPECTROSCOPY
INTRODUCTION TO ABSORPTION AND EMISSION SPECTROSCOPY
Spectroscopy is the measurement and interpretation of electromagnetic radiation absorbed or
emitted when the molecules, or atoms, or ions, of a sample move from one energy state to
another. Every atom, ion, or molecule has a unique and characteristic relationship with
electromagnetic radiation. Areas of spectroscopy may involve changes in the rotational,

2
vibrational, and electronic energies. Other spectroscopic studies may involve energies resulting
from energy changes that arise when a sample is placed in a magnetic field (e.g. N.M.R.) or
electric field (e.g. E.S.R. study).

The Nature of Electromagnetic Radiation

A beam of radiation may be regarded as an electromagnetic wave-form disturbance or photon
of energy propagated at the speed of light. A photon has the properties of a microscopic
particle of definite energy and at the same time has properties of a wave extending over a
broad area of space. The Heisenberg uncertainty principle shows that it is not important or
even possible to measure both the wave and particle properties of a photon simultaneously.
However, it is useful to keep both properties in mind.

A photon originating at a point in space radiates from that point in a spherical wave
characterized by electric field vectors which have periodic maxima perpendicular to the
direction of propagation. The wavelength of the radiation, λ, can be visualized as the distance
between these maxima; that is from crest to crest, as shown in the figure below:

A λ B

3
 P

(e.g. WITH AIR AS MEDIUM)

(MEDIUM OF HIGHER REFRACTIVE INDEX)

Direction of Propagation

Fig. 1: Some Characteristics of Electromagnetic radiation

In the figure, the distance AB is one wavelength.

- The frequency, ν, is the number of waves (or cycles) passing a fixed point, such as P, in a unit
length of time. If E is the energy of a photon, then:
∆E = hν = hc/λ

Where:

h = Planck’s constant and c = the velocity of light in a vacuum, which is about 2.998 x 108 msec-1
or approximately 3.00 x 108 msec-1.

The wavelength (λ) and frequency (ν) are related to the velocity of light (c) by the expression:

λν = c/n

where n = the refractive index (the ratio of the velocity of light in a vacuum to its velocity in the
medium in question).

Sometimes, it is more convenient to use the number of wavelength units in one centimeter.
This number is called the wave-number, ν̅:

ν̅ = 1/λ = νn/c (units, cm-1)
4
 Fig. 2: Schematic representation of molecular Electronic, Vibrational and Rotational
energy levels

The Photoelectric Effect
When sufficiently energetic radiation impinges on a metallic surface, electrons are emitted. The
energy of the emitted electrons is found to be related to the frequency of the incident radiation
by the equation:

E = hν – w

where:

w = the work function, i.e. the work required to remove the electron from the metal to a
vacuum, E = the energy, and ν = the frequency.

N.B. Energy, E is directly dependent upon the frequency, but totally independent of the
intensity of the beam.

Also note that:

- Absorption by polyatomic molecules, particularly in the condensed state, is considerably
more complex than atomic absorption. This is because in the former case, the number
of energy states is greatly enhanced. Here, the total energy of a molecule (E) is given by:
E =Eelectronic + Evibrational + Erotational
Where Eelectronic ,Evibrational , and Erotational represent the respective energies of the molecule.

5
The Electromagnetic Spectrum
Ionizatio-
Energy n of
Chang- atoms
es and
Involv- Inner shell molecul- Valence Spin orientations
ed Nuclear Electrons es electrons Molecular vibrations: (in magnetic field)
X- Near Visib- Electro- Nuclei
ray UV le ns NMR
s Stretching Bending (ESR)
"Soft" Near IR Infrared Far Micro- Radio-
Gamm- X- Vacuum (Overtones) (Fundam- IR waves waves
a rays rays UV ental)
Region
in
Electr-
omag- 1Å 10Å 100Å 200nm 400nm 800nm 0.04cm 25cm
netic 0.8μm 2.5μm 25μm 400μm
Spectr-
um Wavelength
Figure 3: Schematic Diagram of the Electromagnetic Spectrum. Note that the wavelength scale is
non-linear

MOLECULAR ELECTRONIC ENERGY LEVELS

SINGLET

TRIPLET

SINGLET

Inter-atomic distance along critical coordinate
N.B. The curve tails on the right represent the following multiplicities: Topmost (Singlet), Middle
(Triplet) and Bottom (Singlet) as shown.

6
Fig. 4: Schematic diagram for a diatomic molecule Energy levels

Fig. 5: Partial Energy Diagram for a Photo-luminescent System

N.B. Fluorescence lifetime is 10-9 to 10-7 sec., while Phosphorescence lifetime is 10-4 to 10 sec.
or longer.
(To be discussed in details later)

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VIBRATIONAL ENERGY LEVELS
- Vibrational energies are usually an order of magnitude smaller than the electronic
energy.
- For a diatomic molecule, the allowed energies as given by the quantum-mechanical
vibrational energy level, are:
ℎ 𝑘
Evib = (v+½) √µ (v = 0, 1, 2, …………….)
2𝜋
where k = the force constant, i.e. the stiffness of the chemical bond
and µ = the reduced mass for the two atoms, m1 and m2;
m1m2
µ=
m1+m2

RAMAN EFFECT
In Raman spectroscopy, the interaction stems from the electric field and an oscillating
polarizability within the molecule.
Quasi-excited
State Anti-Stokes

Stokes hν0 h(ν0+νm)

hν0 h(ν0-νm)

hνm

Fig. 6: Quantum representation of energy interchange involved in the Raman effect

Laser Sources
- A laser provides an almost ideal monochromatic source of narrow line width.
- It emits radiant energy that is coherent, parallel, and polarized.
- Laser operation involves three principles of physics: stimulated emission, population
inversion, and optical resonance.
- Examples are: He-Ne laser and Ar-Kr laser.

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 Energy transfer
160,000 1s 2s 1s22s22p54s
F via He-Ne 8673 cm-1 (1153 nm)
r collisions 1s22s22p53p
e 15,803 cm-1 (632.8 nm)
q 1s22s22p53s
u EED
e
n CD
c
y
(cm-1)
0 1s2 1s22s22p6
Helium Neon

Key: EED =Excitation by electrical discharge; CD = Collisional deactivation

Fig. 7: Energy levels involved in the He-Ne Laser

INTRODUCTION TO UV-VISIBLE SPECTROSCOPY, AAS, etc.

Spectroscopy
This is the measurement and interpretation of electromagnetic radiation that is
absorbed, emitted or scattered by atoms, molecules or ions.
- Absorption or emission is associated with changes in the energy states of the interacting
species.
- Since each species has characteristic energy states, it may be used to identify and
quantify species in a sample.

Examples

Radiation in UV-Visible region:

- Atomic Absorption Spectrometry
- UV-Visible Spectrophotometry
- Flame Photometry

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 - Atomic Emission Spectrometry
- Atomic fluorescence, phosphorescence Luminescence

Radiation scattering – Turbidimetry

N.B.

Photometer- An instrument that measures the ratio or some function of the two radiant
power(s) of the two beams over a small wavelength range.

- It uses a filter to isolate wavelengths and an inexpensive detector, e.g. Photocell.

Spectrophotometer - An instrument that measures the ratio or some function of the two
radiant power(s) of the two beams over a large wavelength range.

- It uses a monochromator and a very sensitive detector, e.g. Photomultiplier Tube (PMT).
Theory of Beer-Lambert’s Law
- The (practical) UV region generally represents: ≅ 200 - < 400 nm, while
Visible region represents: 400 – 800 nm
- When light is incident upon a homogeneous medium, part of it is absorbed, reflected or
transmitted.

Po(Incident) Pa Pt (transmitted)

Pr (Reflected)

(Absorbed)

Po = Pa +Pt +Pr

- For an all-glass interface, Pr is very small (i.e. ≅ 4%) and may be neglected.
Thus:

Po = Pa +Pt

- If a beam of radiant power, Po, traverses an infinitesimally small distance, δx, of an
absorber, the decrease in radiant power, -δP, is given by:

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 -δP = k’Pδx, since the number of absorbing species is proportional to the thickness of
the medium.
Thus -δP = k’δx …………………………………………………………………………Equation ①
P

or -δP = -δ(ln P) = k’δx
P
Thus, radiant power absorbed is proportional to the thickness traversed.
- If Po is the radiant power at x = 0 and P is the radiant power transmitted at distance x = l,
the equation above can be integrated to give:
𝑃 𝑙
-∫𝑃0 𝑑𝑙𝑛 𝑃 = k’∫0 𝑑𝑥
𝑃0
Thus, giving ln P0 – ln P = ln( ) = k’l ……………………………………….. Equation ②
𝑃
This gives the Lambert’s Law.
- The number of absorbing species that collide with photons is proportional to the
concentration, C.
-dP = k’’PdC
𝑃0
and as above, ln( ) = k”C ……………………………………………………….. Equation ③
𝑃
which gives the Beer’s Law.
- Combining equations ② and ③ gives:
𝑃0
ln ( ) = klC
𝑃
Replacing natural logarithms with base 10 logarithms, gives:
𝑃0
log( ) = abC, where b is the path length and a is a proportionality constant.
𝑃
𝑃0
Absorbance, A, is defined as log ( ). Thus
𝑃
𝑃0
A = log( ) = abC and
𝑃
𝑃
Transmittance is T =
𝑃0
1
i.e. A = log ( ) = -log (T)
𝑇
A = abC where a is the specific absorptivity.
- The proportionality constant, a, is designated as ε, when C is expressed as molar
concentration and path length,l, is in centimeters. Thus giving:
A = εlC
The above is referred to as the Beer-Lambert’s Law.
The units of ε are Mole-1 L cm-1 or mole-1 dm3 cm-1. ε is the molar absorptivity or molar
extinction coefficient.
- Value of molar absorptivity will be different at different wavelengths.

Example

A 0.02 mM solution of standard potassium permanganate has an absorbance of 0.511 when
measured in a 2.0 cm cell at 520 nm. Calculate the concentration of a sample whose

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absorbance is 0.120 when measured in a 1.0 cm cell at the same wavelength (K = 39, Mn = 55,
O = 16).

Solution

A = εCl

For a 2cm cell: 0.511 = ε x 0.02 x 10-3M x 2cm

=> Molar absorptivity, ε = 0.511

2 x 10-5 M x 2cm

Thus ε = 12775 mol-1 L cm-1

For 1.0 cm cell:

0.120 = 12775 x C x 1cm
0.120
=> C = = 9.393 x 10-6 moles/litre
12775 𝑥 1

= 9.393 µM

In ppm,

Rfm for KMnO4 = 39+55+4(16) =39+55+64 = 158 g/mol

1 litre of solution contains 9.393 x 10-6 moles. Thus

1 litre of solution contains 9.393 x 10-6 moles x 158g/mol = 1.4841 x 10-3 g

i.e. 1000 mLof solution contains 1.4841 x 10-3 g

∴ 106 ml of solution contains 1.4841 x 10-3 x 106/103 g = 1.4841 x 10-3 x 103 g

≅1.484 ppm (m/v) or 1.484 mg/L,

or 1.484 µg/ml, etc.

Deviation from Beer-Lambert’s Law

- A plot of absorbance versus concentration should give a straight line.
- However, in practice, there are positive and negative deviations, as shown below in the
following graph of Absorbance versus Concentration.

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Absorbance Expected Linear relation

Concentration

Reasons for deviation

(i) Real deviations
- The Law applies only at low concentrations. At high concentrations (> 10-3 M), refractive
index changes considerably, and so does absorptivity, leading to deviations.

(ii) Instrumental deviations
- Beer’s Law assumes monochromatic light. However, truly monochromatic light may not
be attained.

(iii) Chemical deviations
- Caused by a shift in the position of a chemical or physical equilibrium involving the
absorbing species, e.g. Dissociation or Association:

4C6H5CH2OH ⇌ (C6H5CH2OH)4

Cr2O72- + H2O ⇌ 2HCrO4-
(Orange) (Yellow)

(iv) Presence of impurities that fluoresce or absorb at the particular wavelength.

REGRESSION AND CORRELATION ANALYSIS

Classical methods of Analytical Chemistry are also sometimes referred to as “Wet Chemistry”.
Examples of such methods are Titrimetry and Gravimetry. These can sometimes have high
precision but mainly for major constituents and can handle a few samples.

Classical methods are usually absolute methods, i.e. there are no reference standards required.
They are also tedious, but less costly. On the other hand, instrumental methods can go to low

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concentrations and so are relatively highly sensitive. They are ideal where many samples have
to be analyzed, i.e. they have high sample throughput. They also display multi-component
analysis capability. They also enable interfacing with computers, which affords high degree of
instrumental control and data handling.

Over 90% of all analytical work is currently done by instrumental methods. All instrumental
methods require a calibration step in which standards are treated in the same way as the
samples.

0.35 HYPOTHETICAL INSTRUMENTAL CALIBRATION GRAPH
Instrumental Response e.g.

0.3
e.g. y = 0.713x + 0.001
0.25 R² = 0.999
Absorbance

0.2

0.15

0.1

0.05
Series1
0
0 0.1 0.2 0.3 0.4 0.5
Concentration, in Units (e.g. mg/L)

-
The concentration of the sample is obtained by interpolation (or cross referencing, as
shown in the hypothetical curve drawn above).
This is referred to as the Analytical curve method.
- The calibration curve has to be linear, and given that every point is subject to errors, we
need a best line of fit through the points.
- Statistics provides a mechanism for objectively obtaining the best line of fit and also
specifying errors associated with it. This refers to as Regression analysis.
Assumptions
(1) Errors in calibration experiment occur only in the y-values.
(2) The magnitude of errors in y-values is independent of analyte concentration.
(3) A linear relationship exists between the y- and x- values.
The Product-moment Correlation coefficient (r)
- A straight line has the general equation:
y = bx + a, where b = slope of the curve and a = y-intercept
- For n points on the curve: (x1, y1), (x2, y2), …………………., (xn, yn)

14
 There exists a centroid point (x̅, y̅)
- The product-moment correlation coefficient, r, is used to test how well the points fit a
straight line.
r = ∑𝑖(𝑥𝑖 − 𝑥)(𝑦𝑖 − 𝑦)

2 2
√∑(xi − x̅) ∑(yi– y̅)
𝑖 i

where r takes values: -1 ≤ r ≤ +1 (as illustrated below):

y r =+1 (Perfect positive correlation)

r could be 0.90 y r = 0, i.e.

for other curves No correlation

x

r = -1 (Perfect negative corre- x

lation)

Example

Consider the data:

Conc. (pg/ml) 0.00 2.00 4.00 6.00 8.00 10.00 12.00
(x):

Fluorescence 2.10 5.00 9.00 12.6 17.3 21.0 24.7
intensity (units)
(y):

Calculate the correlation coefficient of the data.

Solution

x̅ = 0.00 + 2.00 + 4.00 + 6.00 + 8.00 + 10.00 + 12.00 = 42.00 = 6.00

7 7

y̅ = 2.10 + 5.00 +9.00 + 12.6 + 17.3 + 21.0 + 24.7 = 91.7 = 13.1

7 7

xi yi (xi-x̅) (xi-x̅)2 (yi-y̅) (yi-y̅)2 (xi-x̅) (yi-y̅)

15
0.00 2.10 -6 +36.0000 -11 121.0000 +66.0000
2.00 5.00 -4 +16.0000 -8.1 65.6100 32.4000
4.00 9.00 -2 +4.0000 -4.1 16.8100 8.2000
6.00 12.6 0 0.0000 -0.5 0.2500 0.0000
8.00 17.3 2 4.0000 +4.2 17.6400 8.4000
10.00 21.0 4 16.0000 +7.9 62.4100 31.6000
12.00 24.7 6 36.0000 +11.6 134.5600 69.6000
TOTALS: 112.0000 418.2800 216.2000
r = ∑𝑖(𝑥𝑖 − 𝑥)(𝑦𝑖 − 𝑦)

2 2
√∑(xi − x̅) ∑(yi– y̅)
𝑖 i

= 216.20000 = 0.9989 (which is > 0.9900, hence very close to +1.0000)

√(112)𝑥(418.28)

This represents good correlation.

The line of Regression of y on x

- Linear relationship is assumed.

Draw best line of fit through the points.

- Since errors are assumed to be in y, we seek the line that minimizes the deviations in
the y-direction between experimental points and the calculated line (i.e. fitted values).
These deviations are referred to as y-residuals.

y

- y - residuals

x

16
 - Since some deviations will be positive and some negative, we try to minimize the sum of
the squares of the residuals, hence the method of Least squares.

- The best line of fit is calculated on this principle.

- The best line of fit must pass through the centroid, i.e. (x̅, y̅).

- It can be shown that for the regression line y = a + bx

𝑏 = ∑(𝑥𝑖 − 𝑥)(𝑦𝑖 − 𝑦)
𝑖

∑𝑖(𝑥𝑖 − 𝑥)2

and since y̅ = a + bx̅, then

a = y̅ – bx̅

which gives the line of regression of y on x.

Using the earlier example:

b = 216.2/112 = 1.93035714285 and a = 13.1 –(6.00 x 1.93) = 13.1 – 11.58 = 1.52

=> y = 1.93x + 1.52 is the regression equation

Thus for a sample that gives fluorescent intensity of 3.00, then:

3.0 = 1.93x + 1.52

=> x = (3.00 – 1.52)/1.93 = 0.7668394 ≅ 0.767 pg/ml.

Errors in Slope and Intercept

- Random errors in y and x are of importance.
From Statistics:
∑𝑖(𝑦𝑖−ŷ𝑖)2
Sy/x = √ (𝑛−2)
where yi = experimental value
ŷ = fitted value = corresponding value on the regression line
n-2 = degrees of freedom, since only two points are needed for a straight line.
- Thus, the standard deviation for slope and intercept are calculated as follows:
𝑆𝑦/𝑥
Sb = 2
√∑𝑖(xi−x̅)
∑𝑖 xi2
and Sa = Sy/x 𝑥√
𝑛 ∑𝑖(xi−x̅)2

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 - Thus, confidence limits on slope and intercept are:
b±tSb and a ± tSa

COMPUTATION RULES (ROUNDING)
(i) MULTIPLICATION AND DIVISION

Example: (a) To Work out the following calculation and round the final answer appropriately:
56𝑥0.003462𝑥43.22
1.684
“Exact Answer” = 4.9757409976…..

The above is rounded as ≅ 5.0

But why is the final answer rounded as above?

Answer: We round to 2 significant figures, which is the least number of significant figures
displayed in the equation (expression) above, i.e. 56 [2 significant figures].

General Rule:

In multiplication or division, the result should contain the same number of significant figures as
that term with the fewest number of significant figures.

Other examples:

(b) A = 𝜋r2 (where A = Area of circle, r = its radius). Calculate A when r = 3.82 units.

Solution:
22
A = ( ) x 3.822 = 3.1428571…. x 3.822 = 3.1428571…. x 14.5924 = 45.86182857….
7

≅ 45.9 𝑎𝑟𝑒𝑎 𝑢𝑛𝑖𝑡𝑠 (i.e. 3 s.f.)
𝐴
(c) C = (Recall A = εbC, where A = absorbance, ε = Extinction coefficient, b = path length and
𝜀𝑏
C = concentration)
1.20
C= = 3.613459123466 x 10-5≅3.61 x 10-5 moles/L (i.e. to 3 s.f.)
33176 𝑥 1.001

Assignment (For marking) – contained in Main Assigment I – Answer all the questions:
35.63 𝑥 0.5481 𝑥 0.05300
Calculate and round appropriately: x 100%
1.1689

(ii) ADDITION AND SUBTRACTION

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General Rule: In addition or subtraction of a set of numbers, all are rounded to the same
number of decimal places. We generally use the lowest number of decimal places.

Examples

Addition
(4
(a) 1.6375 (4 d.p.) (b) 0.0072 (2 s.f.) d.p.)
(2
75.2 (1 d.p.) 12.02 (4 s.f.) d.p.)
(4
6.002 (3 d.p.) 4.0078 (5 s.f.) d.p.)
(1
82.8 (1 d.p.) 25.9 (3 s.f.) d.p.)
(0
4886 (4 s.f.) d.p.)
(i.e. 0 d.p. or whole
N.B. 4927.9278 4928 number)
1.6375+75.2+6.00
2 = 82.8395
82.8 (1 d.p.)

Subtraction
(c) 1.32 x 10-2 ≡ 13.2x10-3 (1 d.p.)

6.72x10-3 6.7 x 10-3 (1 d.p.)
6.5 x 10-3 (1 d.p.)

J.K.U.A.T.

ASSIGNMENT I : COMPUTATION RULES AND ANALYTICAL CHEMISTRY CALCULATIONS (1ST SEMESTER)

19
B. Sc (Analytical Chemistry) – 4th Years

SCH 2450 (MOLECULAR SPECTROSCOPY)

ANSWER ALL THE QUESTIONS
Q1. Express the results of the following calculations using the appropriate number of significant
figures or decimal places.
(i) 15.41 + 14.7
(ii) 58.13 + 5.20 + 20.67 – 12.00
(iii) 71.4 + 0.0074 + 50.35
(iv) (1.412 x 10-5) x (6.1 x 10-6)
(v) 35.63 x 0.5481 x 0.05300 x 100%
1.1689 (5 marks)
Q2. In an analysis of nitrite ions in water supplies, it was found necessary to make up 500 ml
of a solution containing 1000 μg/mL of nitrite ions. The purity of the nitrite used was
95.4 %. (N = 14, O = 16, Na = 23)
(i) Calculate the amount of sodium nitrite that would be required.
(ii) Calculate the concentration (ppm) of sodium ions in the resulting solution.
(5 marks)
Q3 (i) A 2.6 g sample of plant tissue was analyzed and found to contain 3.6 μg of zinc. What
is the concentration of zinc in the plant in (a) ppm (b) ppb? (2 marks)
(ii) Calculate the molar concentrations of 1.00 ppm solutions each of Li+ and Pb2+. (Pb =
207, Li = 6.94) (2 marks)
Q4. Explain briefly how you would round the final answer if the calculation involved all the
four major operations, i.e. addition, subtraction, multiplication and division together.
(1 mark)

TOTAL No. OF MARKS = 15
MOLECULAR ULTRAVIOLET AND VISIBLE ABSORPTION SPECTROSCOPY

Absorbing Species

- Absorption of UV/Visible radiation by atomic or molecular species M is a two-step
process.
(i) M + hν M* i.e. excitation (by absorption)

The lifetime of excited particle is brief (in the range of 10-9 to 10-8 sec.)

(ii) M* M + Relaxation e.g. heat energy, decomposition of M*, etc.

Such a process is called a photochemical reaction. Alternatively, relaxation may involve
fluorescent or phosphorescent reemission of radiation.

Absorbing species can be categorized into three types of electronic transitions: (a) 𝜋, σ, and n
electrons, (b) d and f electrons, and (c) Charge-transfer electrons, i.e. transitions involving
these.

20
ABSORBING SPECIES CONTAINING 𝜋, σ, AND n ELECTRONS

Absorbing species containing 𝜋, σ, and n electrons include organic molecules and ions as well as
a number of inorganic anions. The following diagrams show how σ and 𝜋 bonds are formed.

THEORY

+ + +

s s σ (Bonding molecular orbital)

+ - + -

s s

σ* (Antibonding molecular orbital)

π Orbital (Bonding M.O.)

π* Orbital (Antibonding M.O.)

Figure 9(a): Bonding and antibonding molecular orbitals (M.O.) from 2px atomic
orbitalsSimilarly, when a 2py orbital of one atom overlaps with a 2py orbital of another atom,
they also overlap sidewise forming two molecular orbitals p2py and p*2py. These are exactly
similar to p2px and p*2px molecular orbitals.

21
Energy

σ* σ → σ* n → σ* Antibonding

𝜋* 𝜋→𝜋* n → 𝜋* Antibonding

n Non bonding

𝜋 Bonding

σ Bonding

Figure 9(b): Electronic Molecular Orbital Energy Levels

N.B.

- Sigma (σ) bonds are formed when there is “head-on” atomic orbital overlap and pi (𝜋) bonds
result when there is “parallel” atomic orbital overlap, e.g. parallel overlap of two atomic
orbitals.

- In Organic Chemistry, n (non-bonding) electrons are located principally in the atomic orbitals
of nitrogen, oxygen, sulphur and the halogens.

- UV and Visible radiation absorption promotes electronic transitions as shown above.

- The∆E values for transitions are in the order: n→𝜋* < 𝜋→𝜋* < n→σ*