Infrared Spectroscopy PDF

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This document provides a lecture on infrared spectroscopy, covering topics such as wavelength ranges, regions, and instrumentation. It's useful for students learning organic chemistry.

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INFRARED SPECTROSCOPY
IR spectroscopy :
Infrared spectroscopy is the subset of spectroscopy that deals with the infrared region of the
electromagnetic spectrum. It covers a range of techniques, the most common being a form of
absorption spectroscopy.
Wavelength
The wavelength range of infrared radiation lies between 14000–10 cm−1 (0.8–1000 μm). The
most useful I.R. region lies between 4000 - 670cm-1.
Regions
Near infrared :- approximately 14000–4000 cm−1 (0.8–2.5μm)
Mid infrared :- approximately 4000–400 cm−1 (2.5–30μm)
Far infrared :- approximately 400–10 cm−1 (30–1000 μm)

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 CORRECT WAVELENGTH OF RADIATION

 In any molecule, atoms or groups of atoms are connected by bonds ,which
will be in a continuous motion & will exhibit some frequency. This
frequency is called as natural frequency.

 A molecule absorbs radiation only when
natural frequency = incident frequency.
After absorbing the correct wavelength of radiation, the molecule
vibrates and absorption of infrared radiation takes place and a peak is
observed.

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 A molecule can absorb IR radiation when its absorption causes a change in its
electric dipole.

 Molecule is said to have an electric dipole when there is a slight positive and
negative charge.

 When the molecule having an electric dipole is kept in the electric field ,this
field will exert forces on the electric charges in the molecules.

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 For a molecule to absorb IR, the vibrations within a molecule must cause a net change
in the dipole moment of the molecule.
Dipole moment
 measures the polarity of a chemical bond, or molecule. depends on
 Electronegativity, e.g. H-Cl
 Direction of withdrawing (vector sum)

 Sym st. No absorption
 asymst. Absorption occurs

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 When charged atoms vibrate, they absorb infrared radiation from radiation
source.

 If rate of vibration at charged atoms in a molecule is fast, absorption of radiation
is intense and thus IR spectrum will have intense absorption bands.

 If rate of vibration is slow, weak bands will appear in IR spectrum.

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 1. STRETCHING : Change in inter-atomic distance along bond axis.
 It is of two types:
Symmetrical Asymmetrical

Bonds increase or decrease One bond length increases
in length symmetrically. and the other decreases.

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 2. BENDING: Change in angle between two bonds.

There are four types of bend.
Rocking Scissoring

Bond angle is maintained, but Bond angle decreases.
both bonds move within the plane.

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 Twisting
Wagging

Both atoms move to one side One atom is above the plane and the
of plane. other is below the plane

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1. Sources

2. Monochromators

3. Sample preparation

4. Detectors

5. Typical method

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 IR CHART

Most of Most of
stretching bending
Fnctional fingerprint
group region
frequency
region

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Force constant
(Bond strength)

Reduced mass
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(Fermi Resonance)

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 Infrared Absorption Frequencies

Structural unit Frequency, cm-1
Stretching vibrations (single bonds)
sp C—H 3310-3320
sp2 C—H 3000-3100
sp3 C—H 2850-2950
sp2 C—O 1200
sp3 C—O 1025-1200

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 Infrared Absorption Frequencies

Structural unit Frequency, cm-1
Stretching vibrations (multiple bonds)

C C 1620-1680

—C C— 2100-2200

—C N 2240-2280
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Structural unit Frequency, cm-1
Stretching vibrations (carbonyl groups) C O
Aldehydes and ketones 1710-1750
Carboxylic acids 1700-1725
Acid anhydrides 1800-1850 and 1740-1790
Esters 1730-1750
Amides 1680-1700

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Structural unit Frequency, cm-1
Bending vibrations of alkenes

RCH CH2 910-990

R2C CH2 890

cis-RCH CHR' 665-730

trans-RCH CHR' 960-980

R2C CHR' 790-840

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Structural unit Frequency, cm-1
Bending vibrations of derivatives of benzene
Monosubstituted 730-770 and 690-710
Ortho-disubstituted 735-770
Meta-disubstituted 750-810 and 680-730
Para-disubstituted 790-840
Stretching vibrations (single bonds)
O—H (alcohols) 3200-3600
O—H (carboxylic acids) 3000-3100
N—H 3350-3500
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 Assoc. prof/Miral Ahmed
Associate professor of organic chemistry