High density ratio Lattice Boltzmann simulations of immiscible drop collision

The physics and dynamics of a ternary fluid system are of special interest for a variety of practical applications, including combustion engines, ink-jet printing, and oil recovery. For example, recent experiments demonstrated that if fuel and water droplets are colliding in a combustion chamber, the water can be encapsulated by the fuel. This causes micro-explosions and enhances the burning rate of the combustion chamber. In this contribution, I will present a numerical investigation of the collision between two immiscible droplets by employing a high density ratio (~10³) Free energy Lattice Boltzmann model, which account for the Inertial effects^[1]. I mainly focus on the transition from adhesion to bouncing for a wide range of dimensionless numbers (Weber and Ohnesorge number) and Impact parameter by varying relative surface tension, Impact speed, liquid viscosity and drop size.

References:
[1] M. WÖhrwag, C. Semprebon, A. Mazloomi Moqaddam, I. Karlin, and H. Kusumaatmaja. Ternary free-energy entropic lattice boltzmann model with a high density ratio. Phys. Rev. Lett., 120:234501,
Jun 2018.