THE EFFECT OF HYDRODYNAMIC FLOW-FIELD ON COLLOIDAL STABILITY

Colloid-colloid interactions are important in understanding the macroscopic properties of flowing suspensions. In many processes of technological and biological interest, it is important to identify conditions which promote or inhibit colloidal aggregation. In this paper, we use trajectory analysis to understand the effect of hydrodynamic and nonhydrodynamic forces on colloidal stability. All linear hydrodynamic hows can be represented in a finite region of the tr L(2)-det L plane, where L is the normalized velocity gradient tenser with constant magnitude. We calculate the stability ratio W for different flow types, specified by tr L(2) and det L. For purely attractive interparticle potentials, a small region around simple shear flow (tr L(2) = 0, det L = 0) shows uniquely high stability. Small changes in tr L(2) or det L, which are equivalent to changes in the relative magnitude of vorticity or the relative orientation between vorticity and extension, cause a great decrease in stability. Away from simple shear flow, W is independent of changes in flow type for the entire class of linear flows with open streamlines (tr L(2) greater than or equal to 0). Interparticle potentials with primary and secondary minima exhibit the same stability as purely attractive potentials as long as the Debye screening length is less than a critical value. Greater Debye lengths lead to complete stability (W --> infinity). The critical Debye length depends on fluid flow type and the value of inverse critical Debye length correlates with the strength of the flow field. The magnitude of the particle surface potential has little effect on the stability ratio. Taken together, the results show the type of hydrodynamic flow to be an important determinant of the aggregation behavior of colloidal particles. Furthermore, aggregation in simple shear flow is different than that in other linear flours, and we caution against extrapolating aggregation behavior in simple shear to more complex fluid flow situations. (C) 1994 Academic Press, Inc.