Two-phase flows are of great interest in natural and industrial applications such as rain
formation (Shaw 2003), breaking waves (Melville 1996), spray atomization (Sirignano 1999) …

This review focuses on direct numerical simulations (DNS) of turbulent flows laden with
droplets or bubbles. DNS of these flows are more challenging than those of flows laden with …

We present a neural network-based method for solving linear and nonlinear partial
differential equations, by combining the ideas of extreme learning machines (ELM), domain …

The complex flow modeling based on machine learning is becoming a promising way to
describe multiphase fluid systems. This work demonstrates how a physics-informed neural …

The phase-field method is a popular modeling technique used to describe the dynamics of
microstructures and their physical properties at the mesoscale. However, because in these …

We present a robust and accurate outflow boundary condition and an associated numerical
algorithm for incompressible flow simulations on unbounded physical domains, aiming at …

We propose a novel second order in time numerical scheme for Cahn–Hilliard–Navier–
Stokes phase field model with matched density. The scheme is based on second order …

We present a numerical method for interface-resolved simulations of evaporating two-fluid
flows based on the volume-of-fluid (VoF) method. The method has been implemented in an …

Turbulent flows laden with large, deformable drops are ubiquitous in nature and in a wide
range of industrial processes. Prediction of the interactions between drops, which deform …

We have developed a new pressure-correction method for simulating incompressible two-
fluid flows with large density and viscosity ratios. The method's main advantage is that the …