The influence of a shear field on differently charged bilayers is studied b
y means of rheology, anisotropy of the electrical conductivity, freeze-frac
ture transmission electron microscopy, and small-angle neutron scattering (
SANS). The charge density in the aqueous system tetradecyldimethylamineoxid
e (TDMAO)/tetradecyltrimethylammonium bromide (TTABr)/n-hexanol was varied
by changing the content of TTABr from 0 to 10 mol %. At low TTABr content,
preferentially planar lamellae are formed, and at higher TTABr content, mul
tilamellar, polydisperse vesicles (1 mu m and larger), which are densely pa
cked and therefore possess elastic properties and a yield stress value. It
is shown that the effect of the shear field is such that at first the plana
r lamellae are transformed into vesicles. Once multilamellar vesicles are p
resent, further increase of the shear rate causes vesicle shells to be stri
pped off until, at high shear rates, unilamellar vesicles are formed. This
leads to an increase of the elastic properties and the yield stress value.
The formed unilamellar vesicle system is found to be stable and does not re
lax back into its original state. Thus shearing is prooved to be a suitable
method for control of the morphology of vesicles. The results can be ratio
nalized in terms of the bending elasticity of the bilayer and the position
of the investigated sample in the phase diagram.