Shear-Dependent Interactions in Hydrophobically Modified
Ethylene Oxide Urethane (HEUR) Based Coatings: Mesoscale Structure
and Viscosity
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Abstract
We
have investigated the in situ mesoscale structure of paint formulations
under shear using ultra small-angle neutron scattering (rheo-USANS).
Contrast match conditions were utilized to independently probe the
latex binder particle aggregates and the TiO<sub>2</sub> pigment particle
aggregates. Two different latex chemistries and two different hydrophobically
modified ethylene oxide urethane (HEUR) rheology modifiers were studied.
The rheo-USANS data reveal that both the latex particles and the TiO<sub>2</sub> particles form transient aggregates which are fractal in
nature. The structures depend on the chemistry of the binder particles,
the type of rheology modifier present and the shear stress imposed
upon the formulation. The aggregate size of both the latex and pigment
generally decreases with increasing shear stress. In two of the formulations
studied, the latex and TiO<sub>2</sub> correlation lengths remain
large even at high shear stress and are characteristic of TiO<sub>2</sub> crowding. In a third formulation, shear induces string-like
aggregate structures of TiO<sub>2</sub>, and a further increase in
shear leads to pigment particles becoming more uniformly dispersed.
The changes in the latex and pigment transient aggregate structures
correlate with the changes observed in their viscosity flow curve
profiles. We have used this correlation to develop an elementary viscosity
prediction model based on the structural parameters extracted from
the rheo-USANS data. Using a single fitting parameter and only the
latex transient fractal aggregate structural parameters, good agreement
between the measured and calculated viscosity is obtained. This implies
that the structural parameters extracted from the scattering data
are representative of the colloidal structure under shear and that
energy dissipation from transient fractal aggregates of latex is the
predominant mechanism of viscosity creation in HEUR thickened latex
paints