UV-Visible Spectroscopy PDF

Summary

These are lecture notes for a chemistry course covering UV-Visible Spectroscopy. The slides cover topics such as molecular orbitals, energy levels, and applications. The material appears to be associated with a course at Thapar Institute of Technology in the 2024-2025 academic year.

Full Transcript

UCB009-CHEMISTRY

Molecular Spectroscopy: Brief overview
UV-Visible Spectroscopy

2024-2025 ODD Semester
UCB009 (Chemistry)
An Outline of UV-Visible Spectroscopy:
Revisiting Fundamental Concepts
Covalent bonds in an organic molecule
Energy order of molecular orbitals
Principles of UV-Visible Spectroscopy
Possible Transitions: Allowed and Forbidden transitions
Energy Requirement for Electronic Transitions
W h y  −  * transition is not observed conventionally?
Absorption maxima or λmax
Effect of conjugation on λmax
Relative energies of molecular orbitals
Examples of extended conjugation
Chromophore and Auxochrome
Spectral shifts and effects
Applications of UV-visible spectroscopy

2024-2025 ODD Semester
UCB009 (Chemistry)
 Revisiting Fundamental Concepts
Atomic spectrum:
Line Spectrum
Spectrum of Na

Molecular spectrum:

Band Spectrum

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UCB009 (Chemistry)
 Energy levels in a molecule:

∆E= ∆Etranslational+ ∆Erotational+∆Evibrational +∆Eelectronic

∆Erotational < ∆Evibrational < ∆Eelectronic

Line spectrum appears
due to discrete electronic
transitions in an atom

Band spectrum appears
due to the overlap of
vibrational and rotational
transitions during an
electronic transition in a
molecule

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UCB009 (Chemistry)
UV-Visible Spectroscopy –
Electronic Transitions

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UCB009 (Chemistry)
Energy levels in an atom: Revisiting Fundamental Concepts

s-orbital

p-orbital

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UCB009 (Chemistry)
 Revisiting Fundamental Concepts
Formation of Molecular Orbitals
Linear Combination of Atomic Orbitals (LCAO)

(σ*-orbital)

1) Mixing of s-atomic orbitals

(σ-orbital)

2) Mixing of p-atomic orbitals: Head-on mixing
Energy (E)

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3) Mixing of p-atomic orbitals: Side-ways mixing Revisiting Fundamental Concepts

antibonding
Energy (E)

bonding

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Covalent bonds in an organic molecule

-bond  −bond

   
(bonding) (anti-bonding) (bonding) (anti-bonding)

Compounds containing single bonds, will have σ- and σ*-molecular orbitals.

Compounds containing double or triple bonds will have π-and π* molecular orbitals

Compounds containing hetero atoms [e.g. N, O, S, P, X (=Cl, Br, F, I)] have non-bonding electrons
 Exercise 1:
Find all possible molecular orbitals in the following molecules

1. Methane
2. Ethylene
3. Acetylene
4. Water
5. Pyridine
6. Benzaldehyde
7. Benzoic acid
8. Benzene

Hints to solve the given exercise:
1. Draw the chemical structure of the molecules
2. Show all the bonds explicitly
3. Based on the type of bond present, identify the molecular orbitals
4. If there is any heteroatom in the molecule, identify the additional molecular orbital
Energy order of molecular orbitals:

Concept of HOMO and LUMO:
HOMO (Highest occupied molecular orbital) is the highest energy molecular orbital filled by electrons
LUMO (Lowest unoccupied molecular orbital) is the lowest energy molecular orbital that is empty
LUMO
Energy

HOMO 2024-2025 ODD Semester
UCB009 (Chemistry)
Exercise 2:
Arrange the molecular orbitals available in the following molecules in the order of increasing
energy and identify the HOMO and LUMO

1. Acetone
2. Aniline
3. Acetylene
4. Water
5. Pyridine
6. Benzaldehyde
7. Benzoic acid

Hints to solve the given exercise:
1. Draw the chemical structure of the molecules
2. Show all the bonds explicitly
3. Based on the type of bond present, identify the molecular orbitals
4. If there is any heteroatom in the molecule, identify the additional molecular orbital
5. Arrange the MO in the increasing energy order (Lowest to highest)
6. Identify the highest occupied, which will be HOMO, and the lowest unoccupied, which will be
LUMO
 Principles of UV-Visible Spectroscopy
When a molecule is irradiated with UV-visible light, electronic transitions occur
from bonding orbitals to antibonding orbitals.

The UV radiation region extends from 10 nm to 400 nm, and the visible radiation region extends
from 400 nm to 800 nm.
Near UV Region: 200 nm to 400 nm, Far UV Region: below 200 nm
Far UV spectroscopy is studied under vacuum conditions.
The common solvent used for preparing the sample to be analyzed is either ethyl alcohol or
hexane.

Note: The transition will occur from
Bonding Molecular Orbital (BMO) to Antibonding Molecular Orbital (ABMO)
HOMO (Highest occupied molecular orbital) to LUMO (Lowest unoccupied molecular orbital)
2024-2025 ODD Semester
Lower energy state (filled) to higher energy state (empty)
UCB009 (Chemistry)
 Possible Transitions: Allowed and Forbidden transitions

✓  Symmetry   Symmetry   Symmetry Forbidden
Allowed transitions Forbidden transitions but Observed transitions

* (anti-bonding)
n→* →*
* (anti-bonding)

 n→*
  →*
Energy

→*

 n (non-bonding)

✓ →*
✓  (bonding)

 (bonding)
 Exercise 3:
In the following molecules, find
i) All possible electronic transitions
ii) Allowed transitions
iii) Forbidden transition
1. Methane
2. Ethylene
3. Acetylene
4. Water
5. Pyridine
6. Benzaldehyde
7. Benzoic acid
8. Benzene

Hints to solve the given exercise:
1. Draw the chemical structure of the molecules
2. Show all the bonds explicitly
3. Based on the type of bond present, identify the molecular orbitals
4. If there is any heteroatom in the molecule, identify the additional molecular orbital
5. Write down all possible transitions.
6. Identify the allowed and forbidden transitions.

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UCB009 (Chemistry)
 Energy Requirement for Electronic Transitions

-* > n- * ~ - * > n-*
~150 nm ~170-190 nm 280 nm

-* saturated hydrocarbons e.g. ethane

saturated compounds containing hetero atom(s) having
n-  unshared pairs of electrons. e.g. saturated halides, alcohols,
ethers, aldehydes, amines, etc

compounds having double or triple bond and aromatics e.g.
-*
butadiene, benzene, etc.

unsaturated compounds containing hetero atom having unshared
n-* pair of electrons e.g. carboxylic acids, aldehydes, ketones, etc.
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 Why  -* transition is not observed conventionally?

UV V I B G Y O R
 - * Far UV
~150 nm 100 200 380 760
nm nm nm nm
Vacuum ultraviolet region

σ- σ* requires photons of 150 nm.
Conventional UV-visible spectrophotometer works in the range of 200 nm
to 760 nm.
This instrument cannot be used below 200 nm as oxygen in air strongly
absorbs in far UV region.
Thus, σ- σ* transitions cannot be observed using a conventional UV-
visible spectrophotometer (This transition can be observed only under a
vacuum UV-visible spectrophotometer)

2024-2025 ODD Semester
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Exercise 4
Why σ to σ* transition is not observed by a conventional UV-Vis
spectrophotometer?

Ans. The energy gap between σ – σ* is high and comes below 200 nm wavelength. The general
UV-Vis spectrophotometer provides radiations from 200 nm to 800 nm only not below 200 nm.
That’s why this transition from σ to σ* is not observed (even though it is allowed) by conventional
UV-Vis spectrophotometer.

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Absorption maxima or λmax

max

The wavelength at which a substance shows maximum absorbance is called absorption
maximum or λmax.

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 Effect of conjugation on max
What is conjugation?
When two double bonds are separated by just one single bond, the two double bonds are said to be
conjugated.
CH2 CH3
H 2C H 3C
?
Non-conjugated Conjugated Allenes
(Fun Question)
When double bonds are conjugated in a compound, λmax is shifted to a longer
wavelength.
CH2 CH3
H 2C H 3C
1,5 - hexadiene : λmax = 178 nm 2,4 - hexadiene : λmax = 227 nm

Benzene Styrene
λmax = 255 nm λmax = 274 nm
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 Effect of conjugation on λmax

O O
C C
H 2C CH 2 H 2C
H 3C CH 3 CH 3
Ethylene Acetone Crotonaldehyde
λmax = 171 nm λmax = 279 nm λmax = 290 nm

Conjugation of C=C and carbonyl group shifts the λmax of both groups to longer
wavelengths
Effect of Conjugation:
A comparison of the π-molecular orbital energy levels in the ethylene and 1,3-butadiene

π4*
LUMO
LUMO
π* π*

π3*
Energy

π2
π
HOMO
π
HOMO
π1
Ethylene 1,3 butadiene Ethylene

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UCB009 (Chemistry)
Relative energies of molecular orbitals

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Kemp, W., Organic Spectroscopy, Palgrave Publ.
UCB009 (Chemistry)
Effects of conjugation: Points to remember
Higher the conjugation= lower the gap between HOMO and LUMO= lower the energy
required= Higher the wavelength λmax since, E = hc/

Compounds having 8 or > 8 double bonds in conjugation will appear colored to the human eye

Examples of extended conjugation

-carotene, max = 455 nm

lycopene, max = 474 nm

O
H
N

N
H
O
indigo

λmax for lycopene is at 474 nm in the near blue region of the spectrum – this is absorbed, the complement is now red!
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Λmax for indigo is at 602 nm in the orange region of the spectrum – this is absorbed, and the compliment (Chemistry)
now indigo!
Exercise 5:
Arrange the following molecules in order of increasing λmax.
(i) (a) C6H6 (b) CH2=CH2-CH2-CH2=CH2 (c) C6H5CHO (d) C6H5CH=CH-CH=CH2

Ans. Following is the order:
(i) CH2=CH2-CH2-CH2=CH2 < C6H6 < C6H5CHO < C6H5CH=CH-CH=CH2
(ii) b>a

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 Chromophore and Auxochrome
Chromophore
The functional groups containing multiple bonds capable of absorbing radiations in
the UV/visible region due to -* and n-* transitions e.g.
C=C, C≡C, N=O, N=N, NO2, C=O, C=N, C≡N, C=C,C=S, CONH2, -COOH, etc

Auxochrome
The functional group with non-bonding electrons, that does not absorb radiation in
UV/visible region (200-800 nm), when attached to a chromophore increases the
wavelength and intensity of absorption e.g.
-OH, -OR, -NH2 , -NHR, -NR2, -SH etc.
Chromophore New Chromophore
Chromophore + Auxochrome

λmax = 255 nm 270 nm

New Chromophore
(having increased max)
λmax = 255 nm 280 nm 2024-2025 ODD Semester
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Spectral shifts and effects:

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Bathochromic Shift (Red Shift)

When absorption maximum (max) is shifted towards
longer wavelength, it is known as bathochromic shift
or red shift.

The effect is due to presence of an auxochrome or
by the change of solvent.

For example, an auxochrome group like –OH, -OCH3
causes absorption of compound at longer wavelength

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Why does p-nitrophenol show bathochromic shift (red shift) in the
alkaline medium?

p-nitrophenol, in an alkaline medium, shows a red shift because the negative charge
on the oxygen delocalizes more effectively, leading to a decrease in the HOMO-
LUMO gap.

Conjugation increases
due to negative charge

λmax = 255 nm λmax = 265 nm

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 Hypsochromic Shift (Blue Shift):
When absorption maximum (max) is shifted towards a shorter wavelength, it is known as a
Hypsochromic shift or blue shift.
The effect is due to the removal of conjugation or by the change of solvent.

Why does aniline show Hypsochromic shift (blue shift) in the acidic medium?
Aniline in an acidic medium shows a blue shift because the lone pair of electrons on the nitrogen
is shared with the hydrogen ion, so it is not available for delocalization, leading to an increase in
the HOMO-LUMO gap.

Conjugation decreases
due to protonation

λmax = 280 nm λmax = 265 nm

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 Hyperchromic effect
When the intensity of absorption maximum (max) of a compound increases, it is known
as hyperchromic effect.

Hypochromic effect
When the intensity of absorption maximum (max) of a compound decreases, it is
known as a hypochromic effect.

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Applications of UV-Visible spectroscopy

The extent of conjugation in polyenes can be estimated

Distinction between conjugated and non-conjugated
compounds

Shift in the absorption, due to the addition of unsaturation in
a compound, towards a longer wavelength can be detected.

Presence or absence of a chromophore can be detected..

It is used for characterizing aromatic compounds and
conjugated olefins.

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