Charged  interfaces  189

        concentration and charge number are of primary importance.  R may
         be  a  cation  exchanger  (fixed  negatively  charged  groups,  such  as
         —SO J  or  -COO~) or  an  anion  exchanger  (fixed  positively charged
        groups,  such  as  —NH^).  A  range  of  highly  porous  synthetic cation
        and  anion  exchange  resins  are  available  commercially.  The  porosity
        of  the  resin  facilitates fairly  rapid  ion  exchange,
          The  most important  applications of ion exchange are the  softening
        of  water and  the  'deionisation'  of water.
          In  the  first  of  these  processes,  hard  water  is  passed  through  a
        column  of  a  cation  exchange  resin  usually  saturated  with  sodium
        counter-ions.  The  doubly  charged  (and,  therefore,  more  strongly
        adsorbed)  calcium ions in the water exchange with the singly charged
        sodium  ions  in  the  resin,  thus softening the  water.  Regeneration of
        the  resin  is effected  by passing a strong solution  of  sodium chloride
        through  the column.
          The  'deionisation'  of  water  involves  both  anion  and  cation
        exchange. A cation exchange  resin saturated with hydrogen ions and
        an anion exchange  resin saturated  with hydroxyl ions are used, often
        in  the  form  of  a  mixed  ion  exchange  resin.  These  hydrogen  and
        hydroxyl  ions  exchange  with  the  cations  and  anions  in  the  water
        sample  and  combine  to form  water.
          Ion  exchange  has  many  preparative  and  analytical  uses;  for
        example,  the  separation  of  the  rare  earths  is  usually  achieved  by
        cation  exchange  followed  by  elution  of  their  complexes  with  citric
        acid.

                                     92
        Electrolcinetic phenomena

        Electrokinetic  is the  general  description  applied  to four  phenomena
        which  arise  when attempts  are  made  to  shear  off the  mobile part  of
        the electric double  layer  from  a charged  surface.
          If an electric field is applied  tangentially along a charged  surface,  a
        force  is  exerted  on  both  parts  of  the  electric  double  layer.  The
        charged  surface  (plus  attached  material)  tends  to  move  in  the
        appropriate direction,  while the ions in the  mobile  part  of the  double
        layer show  a net migration  in the opposite direction, carrying  solvent
        along with them, thus causing its flow. Conversely,  an electric field is
        created if the  charged  surface and the  diffuse  part of the double layer
        are made  to  move relative to  each  other.