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The Outer Rim Simulation: A Path to Many-Core Supercomputers

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arxiv 1904.11970 v2 pith:JT3HRERE submitted 2019-04-26 astro-ph.CO

The Outer Rim Simulation: A Path to Many-Core Supercomputers

classification astro-ph.CO
keywords datasimulationbeenchallengesouterwellcarriedcatalogs
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We describe the Outer Rim cosmological simulation, one of the largest high-resolution N-body simulations performed to date, aimed at promoting science to be carried out with large-scale structure surveys. The simulation covers a volume of (4.225Gpc)^3 and evolves more than one trillion particles. It was executed on Mira, a BlueGene/Q system at the Argonne Leadership Computing Facility. We discuss some of the computational challenges posed by a system like Mira, a many-core supercomputer, and how the simulation code, HACC, has been designed to overcome these challenges. We have carried out a large range of analyses on the simulation data and we report on the results as well as the data products that have been generated. The full data set generated by the simulation totals more than 5PB of data, making data curation and data handling a large challenge in of itself. The simulation results have been used to generate synthetic catalogs for large-scale structure surveys, including DESI and eBOSS, as well as CMB experiments. A detailed catalog for the LSST DESC data challenges has been created as well. We publicly release some of the Outer Rim halo catalogs, downsampled particle information, and lightcone data.

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