Improved three-dimensional thermal multiphase lattice Boltzmann model for liquid-vapor phase change

TL;DR

This paper introduces an improved 3D thermal multiphase lattice Boltzmann model that simplifies computations, enhances efficiency, and accurately simulates liquid-vapor phase change without certain previous limitations.

Contribution

The proposed model calculates key gradient terms locally and uses a simpler lattice, improving computational efficiency and accuracy over existing thermal LB models.

Findings

Accurately simulates liquid-vapor phase change.

Reduces computational complexity with D3Q7 lattice.

Validated for improved accuracy and efficiency.

Abstract

Modeling liquid-vapor phase change using the lattice Boltzmann (LB) method has attracted significant attention in recent years. In this paper, we propose an improved three-dimensional (3D) thermal multiphase LB model for simulating liquid-vapor phase change. The proposed model has the following features. First, it is still within the framework of the thermal LB method using a temperature distribution function and therefore retains the fundamental advantages of the thermal LB method. Second, in the existing thermal LB models for liquid-vapor phase change, the finite-difference computations of the gradient terms $\nabla \cdot u$ and $\nabla T$ usually require special treatment at boundary nodes, while in the proposed thermal LB model these two terms are calculated locally. Moreover, in some of the existing thermal LB models, the error term ${\partial _{{t_0}}}\left( {Tu} \right)$ is eliminated by adding local correction terms to the collision process in the moment space, which causes these thermal LB models to be limited to the D2Q9 lattice in two dimensions and the D3Q15 or D3Q19 lattice in three dimensions. Conversely, the proposed model does not suffer from such an error term and therefore the thermal LB equation can be constructed on the D3Q7 lattice, which simplifies the model and improves the computational efficiency. Numerical simulations are carried out to validate the accuracy and efficiency of the proposed thermal multiphase LB model for simulating liquid-vapor phase change.