Rheology  261

         another without weakening the material, the forces  (specific and non-
         specific)  between  them  must be overcome  and then  reinstated  at  the
         same  rate  in new positions.  If the  deforming stress is such that  these
         forces are not reinstated as rapidly as they are overcome, the material
         becomes  structurally  weaker.  The  remaining forces  in certain  cross-
         sections  between  the  structural units  are  then  overcome  even  more
         readily by the  applied  stress,  and cracks might appear  in the  sample.
         Materials  with  low  linear  viscoelastic  limits  are,  therefore,  those
         which  are  readily  work-softened.

        The Weissenberg effect

         A  characteristic  of viscoelastic  behaviour  is the  tendency  for flow to
        occur at right angles to the applied  force.  An extreme example of this
        behaviour is illustrated  in Figure  9.9.  When a rotating  rod  is lowered
        into  a  Newtonian  liquid, the  liquid is set  into  rotation  and  tends  to
        move  outwards,  leaving  a  depression  around  the  rod.  When  the
        rotating  rod  is  lowered  into  a  viscoelastic  liquid,  the  liquid  may
        actually climb up the rod.  The rotation  of the rod causes the liquid  to
        be sheared  circularly and,  because  of  its elastic  nature,  it  acts  like a
        stretched  rubber  band,  tending  to  squeeze  liquid  in  towards  the
        centre  of the  vessel  and,  therefore,  up the  rod.


                                      (b)
















        Figure 9.9  The  Weissenberg  effect:  (a) Newtonian liquid; and  (b) viscoelastic  liquid