Difference between revisions of "Transport in Porous Media"
| Line 14: | Line 14: | ||
are performed to calculate transport and material parameters. | are performed to calculate transport and material parameters. | ||
| + | == Lattice Boltzmann == | ||
| + | The Lattice Boltzmann method numerically solves the discretized Boltzmann equation | ||
| + | using a linerazied collision operator, such as BGK od MRT, to simulate the flow of a Newtonian fluid. | ||
== Current Coworkers == | == Current Coworkers == | ||
* Prof. Dr. [[Rudolf Hilfer]], Project supervisor | * Prof. Dr. [[Rudolf Hilfer]], Project supervisor | ||
* [[Thomas Zauner]], PhD Student | * [[Thomas Zauner]], PhD Student | ||
Revision as of 11:47, 6 May 2009
Introduction
Understanding fluid transport in natural porous media is important for many industrial and scientific applications. Computer simulations require accurate three-dimensional microscopic structure data as input and efficient numerical algorithms for fluid flow simulations. Natural porous media such as carbonates and clay filled sandstones exhibit heterogeneities on many scales and cannot be modeled by existing modeling techniques.
Our Project
A continuum model is developed for generating synthetic microcomputer-tomography data of multiscale porous media at arbitrary resolution. Large scale parallelized lattice-Boltzmann simulations are performed to calculate transport and material parameters.
Lattice Boltzmann
The Lattice Boltzmann method numerically solves the discretized Boltzmann equation using a linerazied collision operator, such as BGK od MRT, to simulate the flow of a Newtonian fluid.
Current Coworkers
- Prof. Dr. Rudolf Hilfer, Project supervisor
- Thomas Zauner, PhD Student