Particle interaction with binary-fluid interfaces in the presence of wetting effects

TL;DR

This paper introduces a comprehensive Eulerian-Lagrangian simulation method for modeling the complex interactions between solid particles and binary-fluid interfaces, incorporating wetting effects and validated through various 2D and 3D cases.

Contribution

The paper presents a novel Eulerian-Lagrangian approach combining phase field and immersed boundary methods to simulate wetting effects in particle-interface interactions.

Findings

Method accurately simulates particle settling and interface interactions.

Wetting properties significantly influence particle submergence and configuration.

Validated with 2D and 3D cases demonstrating robustness and versatility.

Abstract

In this paper, we present an Eulerian-Lagrangian methodology to simulate the interaction between a fluid-fluid interface and a solid particle in the presence of wetting effects. The target physical problem is represented by ternary phase systems in which a solid phase and a drop phase interact inside an incompressible Newtonian carrier fluid. The methodology is based on an Eulerian-Lagrangian approach that allows for the numerical solution of the Continuity and Navier-Stokes equations by using a pseudo-spectral method, whereas the drop phase is modelled by the Phase Field Method, in which a smooth transition layer represented by an hyperbolic function is considered both across the solid-fluid interface and across the drop-fluid interface. Finally, the solid phase is described in the form of a virtual force using the Direct Forcing Immersed Boundary approach. The properties of the immersed solid phase (including wetting effects), the deformability of the drops and the characteristics of the carrier fluid flow are the main controlling parameters. To simulate a ternary phase system, the solid phase is coupled to the binary-fluid phase by introducing a single well potential in the free-energy density functional, which can also control the solid surface wetting property. The capabilities of the methodology are proven by examining first 2D and 3D validation cases in which a solid particle is settling in a quiescent fluid. Then, the interaction of solid particles with a binary-fluid interface and the effects of surface wetting on the submergence of a quasi-buoyant body are discussed. Finally, the equilibrium configuration for a solid particle interacting with an equally-sized drop at different contact angles and the relative rotation of two solid particles bridged by a drop are examined in the case the interaction is induced by shear fluid flow deformations on the drop interface.