Radiative scattering is utilized in the second major spectral method of analysis. In this technique some radiation that passes through a sample strikes particles of the analyte and is scattered in a different direction. A detector is used to measure either the intensity of the scattered radiation or the decreased intensity of the incident radiation. Depending on the scattering mechanism, the method can be employed for either qualitative or quantitative analysis. If the intensity of the scattered radiation is measured, quantitative analysis is performed by preparing a working curve of intensity as a function of concentration of a series of standard solutions (i.e., solutions containing known concentrations of the component being analyzed). Working curves also are used with other analytical methods, including absorptiometry. The intensity of the scattered radiation in the analyte is measured and compared to the working curve. The concentration of the analyte corresponds to the concentration on the curve that has an intensity identical to that of the analyte.
For chemical analysis three forms of radiative scattering are important—namely, Tyndall, Raman, and Rayleigh scattering. Tyndall scattering occurs when the dimensions of the particles that are causing the scattering are larger than the wavelength of the scattered radiation. It is caused by reflection of the incident radiation from the surfaces of the particles, reflection from the interior walls of the particles, and refraction and diffraction of the radiation as it passes through the particles.
Raman and Rayleigh scattering occur when the dimensions of the scattering particles are less than 5 percent of the wavelength of the incident radiation. Both Rayleigh and Raman scattering are caused by the effect on the analyte of the fluctuating electromagnetic field that is associated with the passing incident radiation. The fluctuating field induces an electric dipole (separation of charges equal in size but opposite in sign) within the scattering particles that oscillates at the same frequency as the incident radiation. The oscillating dipole behaves as a point source of emitted radiation.
Scattered radiation can be used to perform quantitative analysis in either of two ways. If the apparatus is designed so that the detector is aligned with the cell and the radiative source, the detector responds to the decreased intensity of the incident radiation that is caused by scattering in the cell. Measurements of the decreased intensity are turbidimetric measurements; the technique is called turbidimetry. The measurements are completely analogous to absorption measurements. The only difference is in the phenomenon that causes the decreased radiative intensity. As with absorption measurements, the decreased intensity is related to the concentration of the scattering species in the cell at a constant wavelength. In both Tyndall scattering and Rayleigh scattering, the wavelength of the scattered radiation is identical to that of the incident radiation. Consequently, neither type provides information that is useful for qualitative analysis.
If the intensity of the scattered radiation is measured, rather than the decrease in intensity of the incident radiation, the method is known as nephelometry. The apparatus used for nephelometric measurements differs from that used for turbidimetric measurements in the placement of the detector. In nephelometry the detector is not aligned with the radiation source and the cell; normally it is placed perpendicular to the path of the incident radiation. Placing the detector out of the path of the incident radiation eliminates the possibility of measuring its intensity. Both nephelometry and turbidimetry are used with Tyndall scattering to quantitatively assay turbid solutions.
As mentioned above, Raman and Rayleigh scattering are caused by induced dipoles that are formed as the electromagnetic radiation passes the scattering particles. Raman scattering differs from Rayleigh scattering in that in the former the induced dipole relaxes to a different vibrational level than it originally had. Accordingly, the wavelength of the scattered radiation differs from the wavelength of the incident radiation by an amount corresponding to the difference between the particle’s original and final vibrational levels. Shifts between the wavelengths of the incident radiation and the scattered radiation correspond to differences in vibrational levels within the scattering molecule and therefore can be used for qualitative analysis in much the same way that infrared spectrophotometry is used.
Another category of spectral analysis in which the incident radiation changes direction is refractometry. The refractive index of a substance is defined as the ratio of the velocity of electromagnetic radiation in a vacuum to its velocity in the medium of interest. Because it is difficult to accurately measure velocities as large as those of electromagnetic radiation, the refractive index is determined from the extent to which the radiation changes direction, owing to the decrease in velocity, as it passes from one medium into another. This phenomenon is refraction. Measurements of refractive index are used to qualitatively analyze pure substances because each substance has a constant and unique refractive index that can be determined with great accuracy. Quantitative analysis of simple mixtures containing known components is possible because the refractive index changes with the composition of the mixture.
A-voltammetric-wave-of-copper-obtained-by-using-a-rotatingFigure 1: A voltammetric wave of copper(II) obtained by using a rotating platinum indicator …[Credits : Encyclopædia Britannica, Inc.]
A-voltammetric-peak-of-gossypol-dissolved-in-methanolFigure 2: A voltammetric peak of gossypol (C30H30O8) dissolved in …[Credits : Encyclopædia Britannica, Inc.]
The-potential-ramps-applied-to-the-indicator-electrode-during-selectedFigure 3: The potential ramps applied to the indicator electrode during selected forms of …[Credits : Encyclopædia Britannica, Inc.]
An-ion-selective-electrode-for-use-in-potentiometric-measurementsFigure 4: An ion-selective electrode for use in potentiometric measurements.[Credits : Encyclopædia Britannica, Inc.]
Electron-density-functions-of-a-few-hydrogen-atom-statesFigure 5: Electron density functions of a few hydrogen atom states. Plots of electron …[Credits : Daniel Kleppner and William P. Spencer, Massachusetts Institute of Technology]
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