A model for transport of interface-confined scalars and insoluble surfactants in two-phase flows

In this work, we propose a novel scalar-transport model for the simulation of scalar quantities that are confined to the interface in two-phase flows. In a two-phase flow, the scalar quantities, such as salts and surfactants, can reside at the interface and can modify the properties of the interface, in the time scales of interest. This confinement of the scalars leads to the formation of sharp gradients of the scalar concentration values at the interface, presenting a serious challenge for its numerical simulations. To overcome this challenge, we propose a computational model for the transport of scalars that maintains the confinement condition for these quantities. The model is discretized using a central-difference scheme, which leads to a non-dissipative implementation that is crucial for the simulation of turbulent flows. The model is used with the ACDI diffuse-interface method (Jain, J. Comput. Phys., 2022), but can also be used with other algebraic-based interface-capturing methods. Furthermore, the provable strengths of the proposed model are: (a) the model maintains the positivity property of the scalar concentration field, a physical realizability requirement for the simulation of scalars, when the proposed criterion is satisfied, (b) the proposed model is such that the transport of the scalar concentration field is consistent with the transport of the volume fraction field, which results in effective discrete confinement of the scalar at the interface; and therefore, prevents the artificial numerical diffusion of the scalar into the bulk region of the two phases. Finally, we present numerical simulations using the proposed model for both one-dimensional and multidimensional cases and assess: the accuracy and robustness of the model, the validity of the positivity property of the scalar concentration field, and the confinement of the scalar at the interface.