Simple Diffusion Hopping Model with Convection
POSTER
Abstract
The transportation of matter in particulate systems has been the subject of significant computational study using a variety of approaches such as particle hopping models. While hopping models fully describe particle diffusion, these models do not capture convective particle motion.
In this study, we present a new variant of a diffusion-hopping model, the convective diffusive lattice model, to model particle flows near bluff obstacles. Particles interact on a square lattice and are subject to excluded volume conditions. In an extension to previous models, we use a continuous velocity field to mediate the particle positions during a convective update after which particles also diffuse. We show an expected wake behind a square obstacle and for larger objects we observe recirculation zones with symmetric vortices in qualitative agreement with experiment and previous simulations.
In this study, we present a new variant of a diffusion-hopping model, the convective diffusive lattice model, to model particle flows near bluff obstacles. Particles interact on a square lattice and are subject to excluded volume conditions. In an extension to previous models, we use a continuous velocity field to mediate the particle positions during a convective update after which particles also diffuse. We show an expected wake behind a square obstacle and for larger objects we observe recirculation zones with symmetric vortices in qualitative agreement with experiment and previous simulations.
*B.W.F. acknowledges financial support from the “Over Grenzen” programme of KNAW (Royal Dutch Academy of Arts and Sciences). J.T.P. acknowledges financial support from the European Research Council (ERC), under its Consolidator Grant scheme, contract no. 615906 (NonSphereFlow). R.v.S. gratefully acknowled
Presenters
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Barry Fitzgerald
- Delft Univ of Tech
- TU Delft