Optical properties  S3

                  Microscopic
                  objective


                              Colloidal
                              dispersion

                              Cardioid
                              consenser





        Figure 3.4  Principle of the  cardioid  dark-field  condenser

        be  separately  visible.  Dark-field  microscopy  is,  nevertheless,  an
        extremely  useful  technique  for  studying colloidal  dispersions  and
        obtaining information  concerning:

        1.  Brownian motion.
        2.  Sedimentation equilibrium.
        3.  Electrophoretic mobility.
        4.  The  progress  of particle  aggregation.
        5.  Number-average particle  size  (from  counting experiments and  a
           knowledge of the  concentration  of dispersed  phase).
        6.  Polydispersity (the larger particles scatter more light and therefore
           appear  to be brighter).
        7.  Asymmetry (asymmetric particles give a flashing  effect,  owing to
           different  scattering intensities for  different  orientations).


                          3 40
        Light scattering ^

        When a beam of light is directed  at a colloidal solution or dispersion,
        some of the  light  may be absorbed  (colour  is produced  when light of
        certain  wavelengths is selectively absorbed),  some  is scattered  and
        the  remainder  is transmitted undisturbed through the  sample. Light
        scattering  results from  the  electric field associated  with  the incident
        light inducing periodic oscillations of the electron clouds of the atoms
        of the material in question -  these then act as secondary sources and
        radiate  scattered  light.