# Implementation of contact angles in the pseudopotential lattice   Boltzmann simulations with curved boundaries

**Authors:** Q. Li, Y. Yu, and Kai H. Luo

arXiv: 1908.04443 · 2019-11-27

## TL;DR

This paper investigates methods to implement contact angles in pseudopotential lattice Boltzmann simulations with curved boundaries, identifying issues with existing schemes and proposing an improved virtual-density approach that reduces unphysical effects.

## Contribution

The authors analyze existing contact angle implementation schemes in pseudopotential LB models and introduce an improved virtual-density scheme suitable for curved boundaries.

## Key findings

- Solid-fluid interaction scheme causes large spurious currents.
- Virtual-density scheme produces unphysical mass-transfer layers.
- Proposed improved virtual-density scheme reduces unphysical effects and retains simplicity.

## Abstract

The pseudopotential multiphase lattice Boltzmann (LB) model is a very popular model in the LB community for simulating multiphase flows. When the multiphase modeling involves a solid boundary, a numerical scheme is required to simulate the contact angle at the solid boundary. In this work, we aim at investigating the implementation of contact angles in the pseudopotential LB simulations with curved boundaries. In the pseudopotential LB model, the contact angle is usually realized by employing a solid-fluid interaction or specifying a constant virtual wall density. However, it is shown that the solid-fluid interaction scheme yields very large spurious currents in the simulations involving curved boundaries, while the virtual-density scheme produces an unphysical thick mass-transfer layer near the solid boundary although it gives much smaller spurious currents. We also extend the geometric-formulation scheme in the phase-field method to the pseudopotential LB model. Nevertheless, in comparison with the solid-fluid interaction scheme and the virtual-density scheme, the geometric-formulation scheme is relatively difficult to implement for curved boundaries and cannot be directly applied to three-dimensional space. By analyzing the features of these three schemes, we propose an improved virtual-density scheme to implement contact angles in the pseudopotential LB simulations with curved boundaries, which does not suffer from a thick mass-transfer layer near the solid boundary and retains the advantages of the original virtual-density scheme, i.e., simplicity, easiness for implementation, and low spurious currents.

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Source: https://tomesphere.com/paper/1908.04443