Abstract
Fluid–fluid interfaces, laden with polymers, particles or other surface-active moieties, often show a rheologically complex response to deformations, in particular when strong lateral interactions are present between these moieties. The response of the interface can then no longer be described by an isotropic surface tension alone. These “structured” soft-matter interfaces are found in many industrial applications, ranging from foods, cosmetics and pharmaceuticals, to oil recovery. Also many biomedical applications involve such interfaces, including those involving lung surfactants and biofilms. In order to understand, design and optimize processes in which structured interfaces are present, flow predictions of how such multiphase systems deform are of the utmost importance, which is the goal of “computational interfacial rheology”, the main topic of this review. We start by rigorously establishing the stress boundary condition used in the computation of multi-phase flows, and show how this changes when the interface is rheologically complex. Then, constitutive models for the extra stress in interfaces, ranging from 2D generalized Newtonian to hyperelastic and viscoelastic, are reviewed extensively, including common pitfalls when applying these models. This is followed by an overview of different approaches to measure interfacial rheological properties, and a discussion of advanced numerical implementations for deforming interfaces. We conclude with an outlook for this relatively young and exciting field.
Highlights
Describing multiphase materials or multiphase material flows invariably involves making constitutive assumptions about the propensity of the interface to transmit stress [1,2,3]
Complex, soft-matter interfaces respond with extra stresses to a deformation, and linear and nonlinear viscoelastic or viscoplastic rheological properties emerge which lead to the field of interfacial rheology [3,11,12]
The treatment of interfaces is typically done using a continuum approach, where the flow in the bulk of each liquid is described by conservation equations for mass, momentum and energy, and appropriate coupling conditions are employed at the liquid–liquid or liquid–fluid interface
Summary
Describing multiphase materials or multiphase material flows invariably involves making constitutive assumptions about the propensity of the interface to transmit stress [1,2,3]. The study of the rheological properties in compression or dilation is more challenging as the interplay between the changes in thermodynamic properties, due to changes in surface concentration, and intrinsic compressional viscoelasticity is difficult to deconvolute [48] Many commercial instruments, such as the popular pendant drop instrument, analyze the response to deformations as if only a surface or interfacial tension is present.
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