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FT-IR Instrument

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Title: FT-IR Instrument


1
FT-IR Instrument
2
Most commercial instruments separate and measure
IR radiation using
  • Dispersive spectrometers or
  • Fourier transform spectrometers.

Dispersive Spectrometers Dispersive
spectrometers, introduced in the mid-1940s and
widely used since, provided the robust
instrumentation required for the extensive
application of this technique.
This consists of three basic components
radiation source, monochromator, and detector
Radiation source
The common radiation source for the IR
spectrometer is an inert solid, heated
electrically to 1000 to 1800 C. Three popular
types of sources are Nernst glower (constructed
of rare-earth oxides), Globar (constructed of
silicon carbide), and Nichrome coil. They all
produce continuous radiations, but with different
radiation energy profiles.
3
Monochromator
  • The monochromator is a device used to disperse a
    broad spectrum of radiation and provide a
    continuous calibrated series of electromagnetic
    energy bands of determinable wavelength or
    frequency range.
  • Prisms or gratings are the dispersive components
    used in conjunction with variable-slit
    mechanisms, mirrors, and filters.

4
Detectors
  • Most detectors used in dispersive IR
    spectrometers can be categorized into two
    classes
  • Thermal detectors and
  • Photon detectors.
  • Thermal detectors include thermocouples,
    thermistors, and pneumatic devices (Golay
    detectors).
  • They measure the heating effect produced by
    infrared radiation. A variety of
  • physical property changes are quantitatively
    determined expansion of a nonabsorbing gas
    (Golay detector), electrical resistance
    (thermistor), and voltage at junction of
    dissimilar metals (thermocouple).

Photon detectors rely on the interaction of IR
radiation and a semiconductor material.
Nonconducting electrons are excited to a
conducting state. Thus, a small current or
voltage can be generated. Thermal detectors
provide a linear response over a wide range of
frequencies but exhibit slower response times and
lower sensitivities than photon detectors.
5
General Concepts Interferometry
  • Optical Interfrometry is an optical measurement
    technique that provides extreme precise
    measurements of distance, displacement or shape
    and surface of objects.
  • It exploits the phenomenon of light waves
    interference .
  • Where under certain conditions a pattern of
    dark and light bars called interference fringes
    can be produced. Fringes can be analyzed to
    present accurate measurements in the range of
    nanometer.
  • The recent developments in laser, fiber optics
    and digital processing techniques have supported
    optical interferometry .
  • Applications ranging from the measurement of a
    molecule size to the diameters of stars.

6
Interference
  • Interference is a light phenomenon .It can be
    seen in everyday life. e.g.. colures of oil film
    floating on water.
  • In electromagnetic waves , interference between
    two or more waves is just an addition or
    superposition process. It results in a new wave
    pattern .

7
Superposition of two waves
  • When two waves with an equal amplitudes are
    superposed the output wave depends on the phase
    between the input waves.
  • Y y1 y2
  • Where y1A1 sin (wt ?1 )
  • y2A2 sin (wt ?2)
  • Since the energy in the light wave is intensity I
    ,which is proportional to the sum of square
    amplitudes A2
  • where AA12A222A1A2 cos (?1 ?2)
  • If A1A2A then
  • A2A22A2 cos (?1 ?2)
  • If y1y2 in phase ,cos(0)1 hence,
  • Y 4A2 ,it gives a bright
    fringe.
  • If y1y2 out of phase by (p)
    ,cos (p)-1 hence,
  • Y 0 ,it gives a
    dark fringe

8
Optical Path Length OPL
  • When light beam travels in space from one point
    to another, the path length is the geometric
    length d multiplied by n (the air refractive
    index) which is one
  • OPL d
  • Light beam travels in different mediums will
    have different optical path, depending on the
    refractive index (n)of the medium or mediums.
  • OPL n d

9
Components
Fourier transform spectrometers
  • Superior speed and sensitivity
  • Instead of viewing each component frequency
    sequentially, as in a
  • Dispersive IR spectrometer, all frequencies are
    examined simultaneously in Fourier transform
    infrared (FTIR) spectroscopy.

Michelson Interferometer
  • Source
  • Michelson Interferometer
  • Sample
  • Detector

10
Sources
  • Black body radiators
  • Inert solids resistively heated to 1500-2200 K
  • Max radiation between 5000-5900 cm-1 (2-1.7 mm),
    falls off to about 1 max at 670 cm-1 (15 mm)
  • Nernst Glower cylinder made of rear earth
    elements
  • Globar- SiC rod
  • CO2 laser
  • Hg arc (Far IR), Tungsten filament (Near IR)

11
Michelson interferometer
  • Configuration
  • Michelson interferometer consists of a
    coherent
  • light source, a beam splitter (BS), a reference
    mirror ,a movable mirror and a screen .
  • Applications
  • There are many measurements that
    Michelson interferometer can be used for,
    absolute distance measurements, optical testing
    and measure gases refractive index.
  • Work method
  • The BS divides the incident beam into two
    parts one travel to the reference mirror and the
    other to the movable mirror .both parts are
    reflected back to BS recombined to form the
    interference fringes on the screen.

12
Sample
  • Sample holder must be transparent to IR- salts
  • Liquids
  • Salt Plates
  • Neat, 1 drop
  • Samples dissolved in volatile solvents- 0.1-10
  • Solids
  • KBr pellets
  • Mulling (warm)(dispersions)
  • Quantitative analysis-sealed cell with
    NaCl/NaBr/KBr windows

13
Detector
  • The two most popular detectors for a FTIR
    spectrometer are
  • deuterated triglycine sulfate (DTGS) and
  • mercury cadmium telluride (MCT).
  • The response times of many detectors (for
    example, thermocouple and thermistor) used in
    dispersive IR instruments are too slow for the
    rapid scan times (1 sec or less) of the
    interferometer.
  • The DTGS detector is a pyroelectric detector that
    delivers rapid responses Because it measures the
    changes in temperature rather than the value of
    temperature.
  • The MCT detector Is a photon (or quantum)
    detector that depends on the quantum nature of
    radiation and also exhibits very Fast responses.
    Whereas DTGS detectors operate at room
    temperature, MCT detectors must be maintained at
    liquid nitrogen temperature (77 K) to be
    effective. In general, the MCT detector is faster
    and more sensitive than the DTGS detector.

14
FTIR Advantages
  • Better speed and sensitivity (Felgett
    advantage). A complete spectrum can be obtained
    during a single scan of the moving mirror, while
    the detector observes all frequencies
    simultaneously.
  • Increased optical throughput (Jaquinot
    advantage). Energy-wasting slits are not required
    in the interferometer because dispersion or
    filtering is not needed.
  • Internal laser reference (Connes advantage). The
    use of a helium neon laser as the internal
    reference in many FTIR systems provides an
    automatic calibration in an accuracy of better
    than 0.01 Cm 1 . This eliminates the need for
    external calibrations.
  • Simpler mechanical design. There is only one
    moving part, the moving mirror, resulting in less
    wear and better reliability.
  • Elimination of stray light and emission
    contributions. The interferometer in FTIR
    modulates all the frequencies. The unmodulated
    stray light and sample emissions (if any) are not
    detected.
  • Powerful data station. Modern FTIR spectrometers
    are usually equipped with a powerful, com-
    puterized data system. It can perform a wide
    variety of data processing tasks such as Fourier
    transformation, interactive spectral subtraction,
    baseline correction, smoothing, integration, and
    library searching.
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