Engineering Chemistry Module I- Molecular Spectroscopy PDF

Summary

This document is a set of lecture notes on engineering chemistry, specifically focusing on module I- Molecular Spectroscopy. The notes explore topics such as rotational energy levels, selection rules, and rotational spectra of diatomic molecules.

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ENGINEERING CHEMISTRY

Lata Pasupulety
Department of Science and Humanities
ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
Class content:

Expression for rotational energy
levels of a diatomic molecule
Selection rules
Rotational spectrum
 ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
Expressions for rotational energy levels for a
Derivation of Moment of Inertia for a heteronuclear
diatomic molecule
diatomic molecule-
rigid rotor model

Source:Fundamentals of Molecular Spectroscopy: C. N.
Banwell and Elaine M McCash, Fifth Edition, MCGRAW-
HILL Education (India) Private Ltd.

A rigid diatomic molecule with masses m1 and m2 joined
by a thin rod of length r 0 = r1 + r2.The centre of mass
is at C
ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
The molecule rotates end- over- end about a point C, the
centre of gravity ,
this is defined by the moment, or balancing, equation:
m1 r1 m2 r2
The moment of inertia about C is defined by
I = m1r12 + m2r22
I m2 r2 r1  m1 r1r2
I r1 r2 (m1  m2 )
m2 ro
Since ,
r1 
m1  m2
mr
Since , r2  1 o
m1  m2
mm
Therefor I  1 2 ro 2 ro 2
e m1  m2 m1 m2

Where μ is the reduced mass m1  m2
given by
 ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
1
E  I 
L
r
2
2

Rotational energy 2 2I ; Since L=Iω

Solving the Schrodinger equation for a rigid rotor shows that angular
momentum is quantised and is given by,

h
where J is the rotational quantum number.

The quantity J , rotational quantum number, which can
take integral values from zero upwards; J=0,1,2,3......
Hence the rotational energy levels are quantised and given
by the expression,
h2
EJ  J ( J  1) Joules
8 2 I
Planck’s constant=6.626×10-34 Js and I is the moment of inertia
 ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
The energy expressed in spectroscopic units(cm ) is given -1

by : h 1  BJ ( J  1)cm  1
  2
J ( J  1)cm which can be written J
J
8 Ic as
h
where 2
cm  1
B
8 Ic
B is known as the rotational
constant

Substituting for values of
J = 0,1,2,3..., we can get the
energies for the rotational
J εJ
levels
0 0
1 2B
2 6B
3 12B
Source:Fundamentals of Molecular Spectroscopy: C. N. Banwell and Elaine M McCash, Fifth
Edition, MCGRAW-HILL Education (India) Private Ltd.
 ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
The selection rules for rigid rotor model obtained after solving
Schodinger equation is :
Gross selection rule – molecule should possess
permanent dipole moment
ΔJ=±1
 J BJ ( J  1)cm  1
Since

For rotational transition
 J ( J 1)  of
2 a
B(molecule
J  1)cm  1 from level J  J +1 , the
energy absorbed is given by

Substituting for values for J = 0,1,2,3....
J Δε(JJ+1)
0 2B cm-1
1 4B cm-1
2 6B cm-1
ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
Rotational energy levels and spectrum

J Δε(JJ+1)
0 2B cm-1
1 4B cm-1
2 6B cm-1
3 8B cm-1
4 10B cm-1

Source:Fundamentals of Molecular Spectroscopy: C. N.
Banwell and Elaine M McCash, Fifth Edition, MCGRAW-
HILL Education (India) Private Ltd.
 ENGINEERING CHEMISTRY
Module I- Molecular
Spectroscopy
Information obtained from the rotational spectrum

Source:http://
www.physics.dcu.ie/~be/
Ps415/Rotational1.pdf

The first line in the spectrum appears at 2B cm-1 and the
distance between any two consecutive lines is constant
and is equal to 2B cm-1. We can get value of ‘B’ from the
spectrum and calculate
h ,I, the moment of inertia using the
1
expression B  2 cm
8 Ic

Since I = µ ro2 , ro can be determined ;
ro is the bond length of the molecule

The spectrum also reveals that some higher rotational
levels are also populated at room temperature
THANK YOU

Lata Pasupulety
Department of Science and Humanities
[email protected]
+91 80 6666 3333 Extn 759