Bead-spring models for an adsorbed polymer molecule in a shear flow
- 15 June 1984
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 80 (12) , 6305-6317
- https://doi.org/10.1063/1.446700
Abstract
A bead‐spring (Rouse‐type) model is used to model an adsorbed fragment of a long‐chain polymer attached to a surface in a steady shear flow. Analytic solution of the moment equations for the case of linear Hookean springs gives the mean configuration, wall traction, and power dissipation of the segment. A Monte Carlo method based on simulation of the stochastic differential equations of motion is used to deal with nonlinear finite‐extension springs. The large increase in hydrodynamic thickness with shear rate found by some experimenters cannot be obtained with these models, although some increase can be obtained if there is an elongational component in the flow, due perhaps to surface nonuniformity or interference between segments.Keywords
This publication has 7 references indexed in Scilit:
- Dynamics of adsorbed polymer chains subjected to flow: The dumbbell modelJournal of Polymer Science: Polymer Physics Edition, 1983
- Adsorption effects in the flow of polymer solutions through capillariesMacromolecules, 1982
- Elongational deformation by shear flow of flexible polymers adsorbed in porous mediaMacromolecules, 1981
- Numerical integration of the Langevin equation: Monte Carlo simulationJournal of Computational Physics, 1980
- The langevin approach to the dumbbell kinetic problem in rheologyJournal of Non-Newtonian Fluid Mechanics, 1978
- Stresses in Dilute Solutions of Bead-Nonlinear-Spring Macromolecules. III. Friction Coefficient Varying with Dumbbell ExtensionTransactions of the Society of Rheology, 1975
- Kinetic Theory and Rheology of Dilute Suspensions of Finitely Extendible DumbbellsIndustrial & Engineering Chemistry Fundamentals, 1972