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7: Components of Optical Instruments

  • Page ID
    333360
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    An early example of a colorimetric analysis is Nessler’s method for ammonia, which was introduced in 1856. Nessler found that adding an alkaline solution of HgI2 and KI to a dilute solution of ammonia produced a yellow-to-reddish brown colloid, in which the colloid’s color depended on the concentration of ammonia. By visually comparing the color of a sample to the colors of a series of standards, Nessler was able to determine the concentration of ammonia. Colorimetry, in which a sample absorbs visible light, is one example of a spectroscopic method of analysis. At the end of the nineteenth century, spectroscopy was limited to the absorption, emission, and scattering of visible, ultraviolet, and infrared electromagnetic radiation. Since then, spectroscopy has expanded to include other forms of electromagnetic radiation—such as X-rays, microwaves, and radio waves—and other energetic particles—such as electrons and ions.

    • 7.1: General Design of Optical Instruments
      The spectroscopic techniques in the chapters that follow use instruments that share several common basic components: a source of energy, a means for holding the sample of interest to us, a device that can isolate a narrow range of wavelengths, a detector for measuring the signal, and a signal processor that displays the signal in a form convenient for the analyst.
    • 7.2: Sources of Radiation
      All forms of spectroscopy require a source of energy to place the analyte in an excited state. In absorption and scattering spectroscopy this energy is supplied by photons. Emission and photoluminescence spectroscopy use thermal, radiant (photon), or chemical energy to promote the analyte to a suitable excited state. In this section we consider the sources of radiant energy.
    • 7.3: Wavelength Selectors
      In optical spectroscopy we measure absorbance or transmittance as a function of wavelength. Unfortunately, we can not isolate a single wavelength of radiation from a continuum source, although we can narrow the range of wavelengths that reach the sample. A wavelength selector passes a narrow band of radiation characterized by a nominal wavelength, an effective bandwidth, and a maximum throughput of radiation. Several types of wavelength selectors are considered in this section.
    • 7.4: Sample Containers
      The sample compartment provides a light-tight environment that limits stray radiation. Samples normally are in a liquid or solution state, and are placed in cells constructed with UV/Vis transparent materials, such as quartz, glass, and plastic.
    • 7.5: Radiation Transducers
      Transducer is a general term that refers to any device that converts a chemical or a physical property into an easily measured electrical signal. The retina in your eye, for example, is a transducer that converts photons into an electrical nerve impulse; your eardrum is a transducer that converts sound waves into a different electrical nerve impulse. A photon transducer takes a photon and converts it into an electrical signal, such as a current, a change in resistance, or a voltage.
    • 7.6: Fiber Optics
      If we need to monitor an analyte’s concentration over time, it may not be possible to remove samples for analysis. This often is the case, for example, when monitoring an industrial production line or waste line, when monitoring a patient’s blood, or when monitoring an environmental system, such as stream. With a fiber-optic probe we can analyze samples in situ.
    • 7.7: Fourier Transform Optical Spectroscopy
      Thus far, the optical benches described in this chapter either use a single detector and a monochromator to pass a single wavelength of light to the detector, or use a multichannel array of detectors and a diffraction grating to disperse the light across the detectors, both of which have limitations. We can overcome these limitations by using an interferometer.

    Thumbnail: A diffraction grating monochromator.


    This page titled 7: Components of Optical Instruments is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by David Harvey.

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