Optical Methods Of Chemical Analysis PDF 2024

Summary

This document is about optical methods of chemical analysis. It covers topics such as absorption, emission, scattering, and reflectance methods, as well as the nature of light. The document also provides a detailed explanation of UV-VIS molecular spectroscopy. It's aimed at a university-level chemistry audience.

Full Transcript

OPTICAL METHODS
OF CHEMICAL ANALYSIS
Light

Sample
Chemical
information
F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024 1
 OPTICAL METHODS OF
CHEMICAL ANALYSIS

1 Absorption 4 Reflectance
methods methods

2 Emission 3 Scattering
methods methods

F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024 2
1 ABSORPTION OF RADIATION

INCIDENT TRANSMITTED
RADIATION RADIATION
(Intensity, Io) sample (Intensity, I)
cell I < Io
I = Io 10- l C

BEER’S LAW
A = log (Io / I) =  l C

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F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 NATURE OF LIGHT

LIGHT

WAVE PARTICLE
wavelength energy
frequency

E = h = h c / 
4
F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 5
F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 UV-VIS MOLECULAR SPECTROSCOPY
Region Wavelength (nm) Energy (J/photon)
Far ultraviolet 10-200 1.99x10-17- 9.93x10-19
Near ultraviolet 200-400 9.93x10-19- 4.96x10-19
Visible 400-800 4.96x10-19- 2.48x10-19
Very near infrared 800-1100 2.48x10-19- 1.81x10-19

Erad < Etrans 
Erad > Etrans  Erad = hc / λ

Erad = Etrans  Erad ? ΔEtrans

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F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 Energy Transfer through Resonance

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F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
INTERACTION OF LIGHT AND MATTER

4p
EXCITED
STATE)

330 nm 3d

819 nm

3p

590 nm

3s

l = 1 GROUND
m = 0, 1 STATE

ATOMIC ABSORPTION SPECTROMETRY MOLECULAR ABSORPTION SPECTROMETRY
F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024 8
INTERACTION OF LIGHT AND MATTER

v3
Electronic
excited v2
state (S1) v1 Rotational
v0 energy
sub-levels

v3
Electronic
ground v2 Vibrational
state (S0) v1 energy
sub-levels
v0

MOLECULAR ABSORPTION SPECTROMETRY
F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024 9
 ABSORPTION
SPECTROSCOPY

4p

Atomic Absorption Molecular Absorption
Spectrometry 3d
Spectrometry
330 nm

819 nm

3p

590 nm

line spectra 3s
band spectra
transitions in transitions in
atomic orbitals molecular orbitals

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F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 ABSORPTION
SPECTROSCOPY

In UV-VIS spectroscopy, Molecular Absorption
only electronic transitions Spectrometry
occur. NO rotational and
vibrational transitions.

Because of the large
number of vibrational
and rotational energy
levels, the absorption
spectra appears as
continuous bands.

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F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 ABSORPTION
SPECTROSCOPY

Atomic Absorption Molecular Absorption
Spectrometry Spectrometry

Atomizer

Sample

LINE BAND
SOURCE SOURCE

Sample

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F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 MOLECULAR ABSORPTION
SPECTROSCOPY

UV-VIS Spectrometry Infra-red Spectrometry
electronic transition vibrational transition
light source: lamps light source: thermal
detector: photoelectric detector: thermal
cell: glass; plastic cell: inorganic salt

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F. Sevilla III / J.H. Bergantin Jr. Methods of Analysis 2024
 FT-IR spectrometers
based on a Michelson
interferometer with one
mirror as movable to
allow a variable delay to
be included in one beam

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F. Sevilla III / J.H. Bergantin Jr. Optical Methods of Analysis 2024
 15
F. Sevilla III / J.H. Bergantin Jr. Optical Methods of Analysis 2024
Skoog, Holler, Crouch. Principles of Instrumental Analysis, 7th ed.
 The output of the interferometer is an interferogram
which stores spectral information from the sample in a
time domain.

F. Sevilla III / J.H. Bergantin Jr. Optical Methods of Analysis 2024
Skoog, Holler, Crouch. Principles of Instrumental Analysis, 7th ed.
 FT-IR spectrometers

Shimadzu IRPrestige-21
optical system

F. Sevilla III / J.H. Bergantin Jr. Optical Methods of Analysis 2024 17
https://www.shimadzu.com/an/ftir/support/tips/letter1/power1.html
 Fourier Transform IR spectrometers

employs frequency modulation to allow multiplex scanning

applies Fourier transform techniques to decode spectra

measures all wavelength simultaneously; performs
multiple rapid scans to improve S/N ratio (Fellgett
advantage)

involves greater intensity of radiation falling on the detector
(Jacquinot advantage)

features accurate and precise wavenumber calibration
through the He-Ne laser internal standard (Connes
advantage)
F. Sevilla III / J.H. Bergantin Jr. Optical Methods of Analysis 2024 18