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Dr.Syed Muzzammil Masaud

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Title: Dr.Syed Muzzammil Masaud


1
Atomic Absorption Atomic Emission Spectroscopy
  • Dr.Syed Muzzammil Masaud
  • Mphill.Pharmaceutical Chemistry

2
BASIC PRINCIPLE

  • ATOMIC ABSORPTION SPECTROSCOPY (AAS) is an
  • analytical technique that measures the
    concentrations of
  • elements. It makes use of the absorption
    of light
  • by these elements in order to measure
    their
  • concentration .

3
  • - Atomic-absorption spectroscopy quantifies the
    absorption of ground state atoms in the gaseous
    state .
  • The atoms absorb ultraviolet or visible light and
    make transitions to higher electronic energy
    levels . The analyte concentration is determined
    from the amount of
  • absorption.

4
  • Concentration measurements are usually determined
    from a working curve after calibrating the
    instrument with standards of known concentration.
  • - Atomic absorption is a very common
    technique for detecting metals and
    metalloids in environmental samples.

5
Elements detectable by atomic absorption are
highlighted in pink in this periodic table
                                                                                             
6
The Atomic Absorption Spectrometer
  • Atomic absorption spectrometers have 4 principal
    components
  • 1 - A light source ( usually a hollow cathode
    lamp )
  • 2 An atom cell ( atomizer )
  • 3 - A monochromator
  • 4 - A detector , and read out device .

7
Schematic Diagram of an Atomic Absorption
Spectrometer


Detector and readout device
Light source (hollow cathode Lamp )
atomizer
monochromator
8
Atomic Absorption Spectrophotometer
9
1 Light Source
  • The light source is usually a hollow cathode
  • lamp of the element that is being measured .
    It contains a tungsten anode and a hollow
    cylindrical cathode made of the element to be
    determined. These are sealed in a glass tube
    filled with an inert gas (neon or argon ) . Each
    element has its own unique lamp which must be
    used for
  • that analysis .

10
Hollow Cathode Lamp
  • cathode

  • Anode

Quartz window
Pyrex body
Anode
Cathode
11
How it works
  • Applying a potential difference between the
    anode and the cathode leads to the ionization of
    some gas atoms .
  • These gaseous ions bombard the cathode and
    eject metal atoms from the cathode in a process
    called sputtering. Some sputtered atoms are in
    excited states and emit radiation characteristic
    of the metal as they fall back to the ground
    state .

12
Scheme of a hollow cathode lamp
13
  • The shape of the cathode which is hollow
    cylindrical concentrates the emitted radiation
    into a beam which passes through a quartz window
  • all the way to the vaporized sample.
  • Since atoms of different elements absorb
  • characteristic wavelengths of light.
    Analyzing
  • a sample to see if it contains a particular
    element means using light from that element .

14
  • For example with lead, a lamp containing lead
    emits light from excited lead atoms that produce
    the right mix of wavelengths to be absorbed by
    any lead atoms from the sample .
  • A beam of the electromagnetic radiation
    emitted from excited lead atoms is passed through
    the vaporized sample. Some of the radiation is
    absorbed by the lead atoms in the sample. The
    greater the number of atoms there is in the vapor
    , the more radiation is absorbed .

15
2 Atomizer
  • Elements to be analyzed needs to be in
    atomic sate
  • Atomization is separation of particles into
  • individual molecules and breaking molecules
    into atoms .This is done by exposing the
    analyte to high temperatures in a flame
    or graphite furnace .

16
  • The role of the atom cell is to primarily
    dissolvate a liquid sample and then the solid
    particles are vaporized into their free gaseous
    ground state form . In this form atoms will be
    available to absorb radiation emitted from the
    light source and thus generate a measurable
    signal proportional to concentration .
  • There are two types of atomization Flame and
    Graphite furnace atomization .

17

18
Flame
  • Flame AA can only analyze solutions , where
  • it uses a slot type burner to increase the
  • path length, and therefore to increase the
    total
  • absorbance .
  • Sample solutions are usually
  • introduced into a nebuliser by being sucked up
    a
  • capillary tube .In the nebuliser the sample is
  • dispersed into tiny droplets , which can be
  • readily broken down in the flame.

19
  • FLAME ATOMIZERS
  • Used in all Atomic Spectroscopic techniques
  • Converts analyte into free atoms in the form of
    vapor phase free atoms
  • Heat is required
  • Routes for sample introduction

20

Various flame atomization techniques
21
Types of Flames Used in Atomic Spectroscopy
22
Processes that take place in flame
23
Effect of flame temperature on excited state
population
atoms in Excited state
Boltzmann constant
Temperature
atoms in Ground state
Energy difference
Statistical factor
24

For Zn N/No 10-15
25
  • Thus 99.998 of Na atoms are in the ground state
  • Atomic emission uses Excited atoms
  • Atomic absorption uses Ground state atoms

26
Effect of flame temperature on excited state
population

27
  • ATOMIZATION DEVICES
  • ATOMIZATION
  • A process of forming free atoms by heat
  • Atomizers are devices that carry out atomization
  • Continuous
  • Non-continuous
  • Continuous (Constant temperature with time)
  • Flame
  • Plasma
  • Non-Continuous (temperature varies with time)
  • Electrothermal
  • Spark discharge

28
  • SAMPLE INTRODUCTION SYSTEMS
  • In continuous atomizers sample is constantly
    introduced in form of droplets, dry aerosol,
    vapor
  • Nebulizer A device for converting the solution
    into fine spray or droplets
  • Continuous sample introduction is used with
    continuous nebulizers in which a steady state
    atomic population is produced. Sample is
    introduced in fixed or discrete amounts.
  • Discontinuous samplers are used with continuous
    atomizers

29
1- Discrete samples are introduced into atomizers
in many ways Electrothermal atomizers a
syringe is used a transient signal is produced
as temperature changes with time and
sample is consumed 2- Indirect insertion
(Probe) sample is introduced into a probe
(carbon rod) and
mechanically moved into the atomization region
vapor cloud is transient because sample
introduced is limited
30
3- Flow Injection The analyte is introduced
into the carrier stream into a nebulizer as
mist 4- Hydride Generation the volatile
sample is stripped from the analyte solution and
carried out by a gas into the atomizer. This
strip is followed by chemically converting the
analyte to hydride vapor form.
31
5- With Arc Spark Solids are employed 6- Laser
Microbe Technique A beam of laser is directed
onto a small solid sample, gets vaporized,
atomized by relative heating. Either sample is
probed by encoding system or vapor produced is
swept into a second absorption or fluorescence
32
  • Nebulization gas is always compressed, usually
    acts as the oxidant it is oxygen (O2) in flame
    and argon (Ar) in plasma
  • Nebulization chambers produce smaller droplets
    and remove or drain larger droplets called
    aerosol modifiers
  • Aspiration rate is proportional to compressed
    gas pressure. The pressure drops through
    capillary, here 1/4 capillary diameters are
    recommended. This is inversely proportional to
    viscocity of the solution
  • Peristaltic and/or syringe pumps could be used

33
  • Oxidant and fuel are usually brought into the
    nebulization chamber through a separate port.
    They mix and pass the burner head called premixed
    burner system.
  • Add organic solvents to reduce the size of the
    drop

34
The Atomic Absorption Spectrometer Sample
Introduction System
Nebuliser
Capillary
Solution
35
  • The fine mist of droplets is mixed with fuel
    ( acetylene ) , and oxidant ( nitrous oxide)
    and burned.
  • The flame temperature is important
    because it influences the distribution of
    atoms. It can be manipulated by
    oxidant and fuel ratio.

36
Graphite Furnace
  • The graphite furnace has several advantages over
    a flame. First it accept solutions, slurries, or
    solid samples.
  • Second it is a much more efficient atomizer than
    a flame and it can directly accept very small
    absolute quantities of sample. It also provides a
    reducing environment for easily oxidized
    elements. Samples are placed directly in the
    graphite furnace and the furnace is electrically
    heated in several steps to dry the sample, ash
    organic matter, and vaporize the analyte atoms.
  • It accommodates smaller samples but its a
    difficult operation, because the high energy that
    is provided to atomize the sample particles into
    ground state atoms might excite the atomized
    particles into a higher energy level and thus
    lowering the precision .

37
3- Monochromators
  • This is a very important part in an AA
    spectrometer. It is used to separate out all of
    the thousands of lines. Without a good
    monochromator, detection limits are severely
    compromised.
  • A monochromator is used to select the specific
    wavelength of light which is absorbed by the
    sample, and to exclude other wavelengths. The
    selection of the specific light allows the
    determination of the selected element in the
    presence of others.

38
4 - Detector and Read out Device
  • The light selected by the monochromator is
    directed onto a detector that is typically a
    photomultiplier tube , whose function is to
    convert the light signal into an electrical
    signal proportional to the light intensity.
  • The processing of electrical signal is
    fulfilled by a signal amplifier . The signal
    could be displayed for readout , or further fed
    into a data station for printout by the requested
    format.

39
Calibration Curve
  • A calibration curve is used to determine the
    unknown concentration of an element in a
    solution. The instrument is calibrated using
    several solutions of known concentrations. The
    absorbance of each known solution is measured and
    then a calibration curve of concentration vs
    absorbance is plotted.
  • The sample solution is fed into the instrument,
    and the absorbance of the element in this
    solution is measured .The unknown concentration
    of the element is then calculated from the
    calibration curve

40
Calibration Curve
  • A 1.0 -
  • b 0.9 -
  • S 0.8 -
    .
  • o 0.7 - .
  • r 0.6 - .
  • b 0.5 - . .
  • a 0.4 - .
  • n 0.3 - .
  • c 0.2 -
  • e 0.1 -
  • 10 20 30 40 50 60
    70 80 90 100

  • Concentration
    ( g/ml )

41
Determining concentration fromCalibration Curve
  • A 1.0 - absorbance measured
  • b 0.9 -
  • S 0.8 -
    .
  • o 0.7 - .
  • r 0.6 - .
  • b 0.5 - . .
  • a 0.4 - .
  • n 0.3 - .
    concentration calculated
  • c 0.2 -
  • e 0.1 -


  • 10 20 30 40 50 60
    70 80 90 100

  • Concentration
    ( mg/l )

42
Interferences
  • The concentration of the analyte element is
    considered to be proportional to the ground state
    atom population in the flame ,any factor that
    affects the ground state atom population can be
    classified as an interference .
  • Factors that may affect the ability of the
    instrument to read this parameter can also be
    classified as an interference .

43
  • The different interferences that are
    encountered in atomic absorption spectroscopy
    are
  • - Absorption of Source Radiation Element other
    than the one of interest may absorb the
    wavelength being used.
  • - Ionization Interference the formation of ions
    rather than atoms causes lower
    absorption of radiation .This problem is
    overcome by adding ionization suppressors.
  • - Self Absorption the atoms of the same kind
    that are absorbing radiation will absorb
    more at the center of the line than at the
    wings ,and thus resulting in the change of
    shape of the line as well as its intensity
    .

44
  • - Back ground Absorption of Source Radiation
  • This is caused by the presence of a particle
    from incomplete atomization .This
    problem is overcome by increasing the flame
    temperature .
  • - Transport Interference
  • Rate of aspiration, nebulization, or transport
    of the sample ( e g viscosity,
    surface tension, vapor pressure ,
    and density ) .

45
2Atomic Emission Spectroscopy
  • Atomic emission spectroscopy is also an
    analytical technique that is used to measure the
    concentrations of elements in samples .
  • It uses quantitative measurement of the emission
    from excited atoms to determine analyte
    concentration .

46
  • The analyte atoms are promoted to a higher
    energy level by the sufficient energy that is
    provided by the high temperature of the
    atomization sources .
  • The excited atoms decay back to lower levels
    by emitting light . Emissions are passed through
    monochromators or filters prior to detection by
    photomultiplier tubes.

47
  • The instrumentation of atomic emission
    spectroscopy is the same as that of atomic
    absorption ,but without the presence of a
    radiation source .
  • In atomic Emission the sample is atomized and
    the analyte atoms are excited to higher energy
    levels all in the atomizer .

48
Schematic Diagram of an Atomic Emission
spectrometer
49
Introduction to AES
  • Atomization Emission Sources
  • Flame still used for metal atoms
  • Electric Spark and Arc
  • Direct current Plasmas
  • Microwave Induced Plasma
  • Inductively Coupled Plasma the most important
    technique
  • Advantages of plasma
  • Simultaneous multi-element Analysis saves
    sample amount
  • Some non-metal determination (Cl, Br, I, and S)
  • Concentration range of several decades (105
    106)
  • Disadvantages of plasma
  • very complex Spectra - hundreds to thousands of
    lines
  • High resolution and expensive optical components
  • Expensive instruments, highly trained personnel
    required

50
10A Plasam Source AES
  • Plasma
  • an electrically conducting gaseous mixture
    containing significant concentrations of cations
    and electrons.
  • Three main types
  • Inductively Coupled Plasma (ICP)
  • Direct Current Plasma (DCP)
  • Microwave Induced Plasma (MIP)

51
ICP
  • Inductively Coupled Plasma (ICP)
  • Plasma generated in a device called a Torch
  • Torch up to 1" diameter
  • Ar cools outer tube, defines plasma shape
  • Rapid tangential flow of argon cools outer quartz
    and centers plasma
  • Rate of Argon Consumption 5 - 20 L/Min
  • Radio frequency (RF) generator 27 or 41 MHz up to
    2 kW
  • Telsa coil produces initiation spark
  • Ions and e- interact with magnetic field and
    begin to flow in a circular motion.
  • Resistance to movement (collisions of e- and
    cations with ambient gas) leads to ohmic heating.
  • Sample introduction is analogous to atomic
    absorption.

52
Sample introduction
  • Nebulizer
  • Electrothermal vaporizer
  • Table 8-2 methods of sample introducton

53
Nebulizer
  • convert solution to fine spray or aerosol
  • Ultrasonic nebulizer
  • uses ultrasound waves to "boil" solution flowing
    across disc
  • Pneumatic nebulizer
  • uses high pressure gas to entrain solution

54
Electro-thermal vaporizer ETV
  • Electrothermal vaporizer (ETV)
  • electric current rapidly heats crucible
    containing sample
  • sample carried to atomizer by gas (Ar, He)
  • only for introduction, not atomization

55
Plasma structure
  • Brilliant white core
  • Ar continuum and lines
  • Flame-like tail
  • up to 2 cm
  • Transparent region
  • where measurements are made (no continuum)

56
Plasma characteristics
  • Hotter than flame (10,000 K) - more complete
    atomization/ excitation
  • Atomized in "inert" atmosphere
  • Ionization interference small due to high density
    of e-
  • Sample atoms reside in plasma for 2 msec and
  • Plasma chemically inert, little oxide formation
  • Temperature profile quite stable and uniform.

57
DC plasma
  • First reported in 1920s
  • DC current (10-15 A) flows between C anodes and W
    cathode
  • Plasma core at 10,000 K, viewing region at 5,000
    K
  • Simpler, less Ar than ICP - less expensive
  • Less sensitive than ICP
  • Should replace the carbon anodes in several hours

58
Atomic Emission Spectrometer
  • May be gt1,000 visible lines (lt1 Å) on continuum
  • Need
  • higher resolution (lt0.1 Å)
  • higher throughput
  • low stray light
  • wide dynamic range (gt1,000,000)
  • precise and accurate wavelength
    calibration/intensities
  • stability
  • computer controlled
  • Three instrument types
  • sequential (scanning and slew-scanning)
  • Multichannel - Measure intensities of a large
    number of elements (50-60) simultaneously
  • Fourier transform FT-AES

59
Desirable properties of an AE spectrometer
60
Sequential vs. multichannel
  • Sequential instrument
  • PMT moved behind aperture plate,
  • or grating prism moved to focus new l on exit
    slit
  • Pre-configured exit slits to detect up to 20
    lines, slew scan
  • characteristics
  • Cheaper
  • Slower
  • Multichannel instrument
  • Polychromators (not monochromator) - multiple
    PMT's
  • Array-based system
  • charge-injection device/charge coupled device
  • characteristics
  • Expensive ( gt 80,000)
  • Faster

61
Sequential vs. multichannel
62
Sequential monochromator
  • Slew-scan spectrometers
  • even with many lines, much spectrum contains no
    information
  • rapidly scanned (slewed) across blank regions
    (between atomic emission lines)
  • From 165 nm to 800 nm in 20 msec
  • slowly scanned across lines
  • 0.01 to 0.001 nm increment
  • computer control/pre-selected lines to scan

63
Slew scan spectrometer
  • Two slew-scan gratings
  • Two PMTs for VIS and UV
  • Most use holographic grating

64
Scanning echelle spectrometer
  • PMT is moved to monitor signal from slotted
    aperture.
  • About 300 photo-etched slits
  • 1 second for moving one slit
  • Can be used as multi channel spectrometer
  • Mostly with DC plasma source

65
AES instrument types
  • Three instrument types
  • sequential (scanning and slew-scanning)
  • Multichannel - Measure intensities of a large
    number of elements (50-60) simultaneously
  • Fourier transform FT-AES

66
Multichannel polychromator AES
  • Rowland circle
  • Quantitative det.
  • 20 more elements
  • Within 5 minutes

In 10 minutes
67
Applications of AES
  • AES relatively insensitive
  • small excited state population at moderate
    temperature
  • AAS still used more than AES
  • less expensive/less complex instrumentation
  • lower operating costs
  • greater precision
  • In practice 60 elements detectable
  • 10 ppb range most metals
  • Li, K, Rb, Cs strongest lines in IR
  • Large of lines, increase chance of overlap

68
Detection power of ICP-AES
69
ICP/OES INTERFERENCES
  • Spectral interferences
  • caused by background emission from continuous or
    recombination phenomena,
  • stray light from the line emission of high
    concentration elements,
  • overlap of a spectral line from another element,
  • or unresolved overlap of molecular band spectra.
  • Corrections
  • Background emission and stray light compensated
    for by subtracting background emission determined
    by measurements adjacent to the analyte
    wavelength peak.
  • Correction factors can be applied if interference
    is well characterized
  • Inter-element corrections will vary for the same
    emission line among instruments because of
    differences in resolution, as determined by the
    grating, the entrance and exit slit widths, and
    by the order of dispersion.

70
Physical interferences of ICP
  • cause
  • effects associated with the sample nebulization
    and transport processes.
  • Changes in viscosity and surface tension can
    cause significant inaccuracies,
  • especially in samples containing high dissolved
    solids
  • or high acid concentrations.
  • Salt buildup at the tip of the nebulizer,
    affecting aerosol flow rate and nebulization.
  • Reduction
  • by diluting the sample
  • or by using a peristaltic pump,
  • by using an internal standard
  • or by using a high solids nebulizer.

71
Interferences of ICP
  • Chemical interferences
  • include molecular compound formation, ionization
    effects, and solute vaporization effects.
  • Normally, these effects are not significant with
    the ICP technique.
  • Chemical interferences are highly dependent on
    matrix type and the specific analyte element.

72
Memory interferences
  • When analytes in a previous sample contribute to
    the signals measured in a new sample.
  • Memory effects can result
  • from sample deposition on the uptake tubing to
    the nebulizer
  • from the build up of sample material in the
    plasma torch and spray chamber.
  • The site where these effects occur is dependent
    on the element and can be minimized
  • by flushing the system with a rinse blank between
    samples.
  • High salt concentrations can cause analyte signal
    suppressions and confuse interference tests.

73
Typical Calibration ICP curves
74
Calibration curves of ICP-AES
75
10B. Arc and Spark AES
  • Arc and Spark Excitation Sources
  • Limited to semi-quantitative/qualitative analysis
    (arc flicker)
  • Usually performed on solids
  • Largely displaced by plasma-AES
  • Electric current flowing between two C electrodes

76
Carbon electrodes
  • Sample pressed into electrode or mixed with Cu
    powder and pressed - Briquetting (pelleting)
  • Cyanogen bands (CN) 350-420 nm occur with C
    electrodes in air -He, Ar atmosphere
  • Arc/spark unstable
  • each line measured gt20 s
  • needs multichannel detection

77
Arc and Spark spectrograph
78
spectrograph
  • Beginning 1930s
  • photographic film
  • Cheap
  • Long integration times
  • Difficult to develop/analyze
  • Non-linearity of line "darkness
  • Gamma function
  • Plate calibration

79
Multichannel photoelectric spectrometer
  • multichannel PMT instruments
  • for rapid determinations (lt20 lines) but not
    versatile
  • For routine analysis of solids
  • metals, alloys, ores, rocks, soils
  • portable instruments
  • Multichannel charge transfer devices
  • Recently on the market
  • Orignally developed for plasma sources

80
Comparison Between Atomic Absorption and
Emission Spectroscopy
  • Absorption
  • - Measure trace metal concentrations in
    complex matrices .
  • - Atomic absorption depends upon
    the number of ground state
  • atoms .
  • Emission
  • - Measure trace metal concentrations
    in complex matrices .
  • - Atomic emission depends upon the number of
    excited atoms .

81
  • - It measures the radiation
    absorbed by the ground state atoms.
  • - Presence of a light source ( HCL )
    .
  • - The temperature in the atomizer is
    adjusted to atomize the analyte atoms in
    the ground state only.
  • - It measures the radiation
    emitted by the excited atoms .
  • - Absence of the light source .
  • - The temperature in the atomizer is big
    enough to atomize the analyte atoms and
    excite them to a higher energy level.
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