A prospect for computing in porous materials research: Very large fluid flow simulations

•A very large, steady-state fluid flow simulation in a porous material is presented.•The simulation involves 16,3843 lattice cells (590 billion of them are pore sites).•The achieved system size exposes new opportunities in porous materials research.•In a benchmark simulation, 1.77 PFLOPS performance...

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Veröffentlicht in:Journal of computational science 2016-01, Vol.12 (C), p.62-76
Hauptverfasser: Mattila, Keijo, Puurtinen, Tuomas, Hyväluoma, Jari, Surmas, Rodrigo, Myllys, Markko, Turpeinen, Tuomas, Robertsén, Fredrik, Westerholm, Jan, Timonen, Jussi
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Sprache:eng
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Zusammenfassung:•A very large, steady-state fluid flow simulation in a porous material is presented.•The simulation involves 16,3843 lattice cells (590 billion of them are pore sites).•The achieved system size exposes new opportunities in porous materials research.•In a benchmark simulation, 1.77 PFLOPS performance is observed with 16,384 GPUs. Properties of porous materials, abundant both in nature and industry, have broad influences on societies via, e.g. oil recovery, erosion, and propagation of pollutants. The internal structure of many porous materials involves multiple scales which hinders research on the relation between structure and transport properties: typically laboratory experiments cannot distinguish contributions from individual scales while computer simulations cannot capture multiple scales due to limited capabilities. Thus the question arises how large domain sizes can in fact be simulated with modern computers. This question is here addressed using a realistic test case; it is demonstrated that current computing capabilities allow the direct pore-scale simulation of fluid flow in porous materials using system sizes far beyond what has been previously reported. The achieved system sizes allow the closing of some particular scale gaps in, e.g. soil and petroleum rock research. Specifically, a full steady-state fluid flow simulation in a porous material, represented with an unprecedented resolution for the given sample size, is reported: the simulation is executed on a CPU-based supercomputer and the 3D geometry involves 16,3843 lattice cells (around 590 billion of them are pore sites). Using half of this sample in a benchmark simulation on a GPU-based system, a sustained computational performance of 1.77 PFLOPS is observed. These advances expose new opportunities in porous materials research. The implementation techniques here utilized are standard except for the tailored high-performance data layouts as well as the indirect addressing scheme with a low memory overhead and the truly asynchronous data communication scheme in the case of CPU and GPU code versions, respectively.
ISSN:1877-7503
1877-7511
DOI:10.1016/j.jocs.2015.11.013