Page 62 - Introduction to Colloid and Surface Chemistry
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5 2 Optical properties
focus is extremely valuable in the study of the contours of solid
surfaces and in the study of particle shape and orientation.
Dark-field microscopy-the ultramicroscope
Dark-field illumination is a particularly useful technique for detecting
the presence of, counting and investigating the motion of suspended
colloidal particles. It is obtained by arranging the illumination system
of an ordinary microscope so that light does not enter the objective
unless scattered by the sample under investigation.
If the particles in a colloidal dispersion have a refractive index
sufficiently different from that of the suspending medium, and an
intense illuminating beam is used, sufficient light is deflected into the
objective for the particles to be observed as bright specks against a
dark background. Lyophobic particles as small as 5-10 nm can be
made indirectly visible in this way. Owing to solvation, the refractive
index of lyophilic particles, such as dissolved macromolecules, is little
different from that of the suspending medium, and they scatter
insufficient light for detection by dark-field methods.
The two principal techniques of dark-field illumination are the slit
and the cardioid methods. In the slit ultramicroscope of Siedentopf
and Zsigmondy (1903) the sample is illuminated from the side by an
intense narrow beam of light from a carbon-arc source (Figure 3.3).
The cardioid condenser (a standard microscope accessory) is an
optical device for producing a hollow cone of illuminating light; the
sample is located at the apex of the cone, where the light intensity is
high (Figure 3.4).
Dark-field methods do not help to improve the resolving power of
a microscope. A small scattering particle is seen indirectly as a weak
blur. Two particles must be separated by the resolution distance 8 to
Carbon-arc Microscope
light source
Adjustable Colloidal
slit dispersion
Figure 3.3 Principle of the slit ultramicroscope
