Mechanistic constitutive model for wormlike micelle solutions with flow-induced structure formation

TL;DR

This paper introduces a tensor constitutive model for dilute wormlike micellar solutions that predicts stress and flow-induced structure formation, capturing complex viscosity behaviors and multivalued stress-rate relations consistent with experimental observations.

Contribution

The model uniquely combines flow-induced alignment and dynamic rod length variation, providing a simple yet effective framework for simulating micellar solution rheology.

Findings

Viscosity increases then decreases with deformation rate.

Predicts multivalued stress-rate relations at high flow rates.

Agrees reasonably with experimental flow data.

Abstract

We present a tensor constitutive model for predicting stress and flow-induced structure formation in dilute wormlike micellar solutions. The micellar solution is treated as a dilute suspension of rigid Brownian rods whose length varies dynamically. Consistent with the mechanism presented by Turner and Cates [J. Phys.:~Condens. Matter 4, 3719 (1992)], flow-induced alignment of the rods is assumed to promote increase of rod length that corresponds to the formation of flow-induced structures observed in experiments. At very high deformation rate, hydrodynamic stresses causes the rod length to decrease. These mechanisms are implemented in a phenomenological equation governing the evolution of rod length, with the number density of rods appropriately modified to ensure conservation of surfactant mass. The model leads first to an increase in both shear and extensional viscosity as deformation rate increases and then to a decrease at higher rates. If the rate constant for flow-induced rod growth is sufficiently large, the model predicts a multivalued relation between stress and deformation rate in both shear and uniaxial extension. Predictions for shear and extensional flow at steady state are in reasonable agreement with experimental results. By design, the model is simple enough to serve as a tractable constitutive relation for computational fluid dynamics studies.