English

MFC: An open-source high-order multi-component, multi-phase, and multi-scale compressible flow solver

Computational Physics 2020-08-19 v1 Fluid Dynamics

Abstract

MFC is an open-source tool for solving multi-component, multi-phase, and bubbly compressible flows. It is capable of efficiently solving a wide range of flows, including droplet atomization, shock-bubble interaction, and gas bubble cavitation. We present the 5- and 6-equation thermodynamically-consistent diffuse-interface models we use to handle such flows, which are coupled to high-order interface-capturing methods, HLL-type Riemann solvers, and TVD time-integration schemes that are capable of simulating unsteady flows with strong shocks. The numerical methods are implemented in a flexible, modular framework that is amenable to future development. The methods we employ are validated via comparisons to experimental results for shock-bubble, shock-droplet, and shock-water-cylinder interaction problems and verified to be free of spurious oscillations for material-interface advection and gas-liquid Riemann problems. For smooth solutions, such as the advection of an isentropic vortex, the methods are verified to be high-order accurate. Illustrative examples involving shock-bubble-vessel-wall and acoustic-bubble-net interactions are used to demonstrate the full capabilities of MFC.

Keywords

Cite

@article{arxiv.1907.10512,
  title  = {MFC: An open-source high-order multi-component, multi-phase, and multi-scale compressible flow solver},
  author = {Spencer H. Bryngelson and Kevin Schmidmayer and Vedran Coralic and Jomela C. Meng and Kazuki Maeda and Tim Colonius},
  journal= {arXiv preprint arXiv:1907.10512},
  year   = {2020}
}

Comments

25 pages, 8 figures, 2 tables. Submitted to Computer Physics Communications

R2 v1 2026-06-23T10:29:33.875Z