화학공학소재연구정보센터
Langmuir, Vol.19, No.8, 3304-3312, 2003
Interfacial slip violations in polymer solutions: Role of microscale surface roughness
Violations of the no-slip hydrodynamic boundary condition are investigated in polymer solutions using gap-dependent shear flow measurements between parallel plates. Solutions of high molar mass, 3.8 x 10(6) less than or equal to M-w less than or equal to 20.06 x 10(6), narrow molecular weight distribution polystyrene, PS, in diethyl phthalate, DEP (a good solvent of low volatility), are the main focus of the study. Violations of the no-slip condition in these systems are evident from an apparent reduction in solution viscosity as the plate separation is reduced. Viscosity measurements at multiple plate separations allow the slip velocity V, and slip extrapolation length b to be quantified. This article reports b and V-s for polymer solutions over a wide range of shear stress and solution concentrations, 0.025 less than or equal to phi less than or equal to 0.079, that is, for polymer solutions spanning the range from marginally entangled to highly entangled liquids. For the most entangled solutions studied, extremely large extrapolation lengths, b > 200 mum, are observed. Extrapolation lengths b ranging from 2 to 30 mum are observed for less entangled PS/DEP solutions, indicating that significant levels of slip are possible even in moderately entangled polymer liquids. The extrapolation length is also reported to manifest a nonmonotonic but universal dependence on shear stress for the solutions studied. These observations are compared with expectations for slip by polymer depletion, adhesive failure, and polymer disentanglement processes. The effect of surface roughness on slip violations is also investigated using parallel plate fixtures roughened by attaching a single layer of micro- or nanosized silica glass spheres. Surfaces with root-mean-square (rms) roughness, Rq, ranging from molecularly smooth to macroscopically rough, 9 nm less than or equal to Rq less than or equal to 1.4 x 10(4) nm, are created using this procedure. We find that rms surface roughness Rq greater than or equal to 0.65Rg effectively eliminates interfacial slip violations in entangled polymer solutions. This finding is discussed in terms of the mechanism of slip in entangled polymer systems.