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# waLBerla
-waLBerla (widely applicable Lattice Boltzmann from Erlangen) is a massively
-parallel framework for multi physics applications. Besides its original
-objective, Lattice Boltzmann solvers for hydrodynamics, it now contains
-modules for other applications like Multigrid and rigid body dynamics
-as well. Great emphasis is placed on the interoperability between the modules
-in particular the fluid-particle coupling.
-It scales from laptops to current and future supercomputers while maintaining
+waLBerla (widely applicable Lattice Boltzmann from Erlangen) is a massively
+parallel framework for multi physics applications. Besides its original
+objective, Lattice Boltzmann solvers for hydrodynamics, it now contains
+modules for other applications like Multigrid and rigid body dynamics
+as well. Great emphasis is placed on the interoperability between the modules
+in particular the fluid-particle coupling.
+It scales from laptops to current and future supercomputers while maintaining
near-perfect efficiency.
See https://www.walberla.net/ for more information and a showcase of applications.
@@ -48,27 +48,28 @@ Many thanks go to waLBerla's [contributors](AUTHORS.txt)
If you use waLBerla in a publication, please cite the following articles:
Overview:
- - M. Bauer et al, *waLBerla: A block-structured high-performance framework for
- multiphysics simulations*. Computers & Mathematics with Applications, 2020,
+ - M. Bauer et al, *waLBerla: A block-structured high-performance framework for
+ multiphysics simulations*. Computers & Mathematics with Applications, 2020.
https://doi.org/10.1016/j.camwa.2020.01.007.
-
+
Grid Refinement:
- - F. Schornbaum and U. Rüde, *Massively parallel algorithms for the lattice boltzmann
- method on nonuniform grids*. SIAM Journal on Scientific Computing, 2016.
+ - F. Schornbaum and U. Rüde, *Massively parallel algorithms for the lattice boltzmann
+ method on nonuniform grids*. SIAM Journal on Scientific Computing, 2016.
https://doi.org/10.1137/15M1035240
-
-LBM - Particles Coupling:
- - C. Rettinger and U. Rüde, *Dynamic load balancing techniques for particulate flow simulations*.
- Computation, 2019. https://doi.org/10.3390/computation7010009
-
+
+LBM - Particle Coupling:
+ - C. Rettinger and U. Rüde, *A comparative study of fluid-particle coupling methods for
+ fully resolved lattice Boltzmann simulations*. Computers & Fluids, 2017.
+ https://doi.org/10.1016/j.compfluid.2017.05.033
+
MESA-PD:
- - S. Eibl and U. Rüde, *A Modular and Extensible Software Architecture for Particle Dynamics*.
+ - S. Eibl and U. Rüde, *A Modular and Extensible Software Architecture for Particle Dynamics*.
Proceedings Of The 8Th International Conference On Discrete Element Methods.
https://mercurylab.co.uk/dem8/full-papers/#page-content
-
+
Carbon Nanotubes:
- - G. Drozdov et al, *Densification of single-walled carbon nanotube films:
- Mesoscopic distinct element method simulations and experimental validation*.
+ - G. Drozdov et al, *Densification of single-walled carbon nanotube films:
+ Mesoscopic distinct element method simulations and experimental validation*.
Journal of Applied Physics, 2020. https://doi.org/10.1063/5.0025505
## License