Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation

Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation

As an entry for the 2001 Gordon Bell Award in the "special" category, we describe our 3-d, hybrid, adaptive mesh refinement (AMR) code Enzo designed for high-resolution, multiphysics, cosmological structure formation simulations. Our parallel implementation places no limit on the depth or...

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Main Authors: Greg L. Bryan, Tom Abel, Michael L. Norman
Format: Article
Language:English
Published: Hindawi Limited 2002-01-01
Series:Scientific Programming
Online Access:http://dx.doi.org/10.1155/2002/423041
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spelling doaj-0876aaf7434c4e8a931daa2377ad5af12021-07-02T01:49:18ZengHindawi LimitedScientific Programming1058-92441875-919X2002-01-0110429130210.1155/2002/423041Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star FormationGreg L. Bryan0Tom Abel1Michael L. Norman2Physics Department, University of Oxford, Oxford, OX1 3RH, UKHarvard-Smithsonian CFA, Cambridge, MA 02138, USALab. for Computational Asrophysics, UC San Diego, La Jolla, CA 92093-0424, USAAs an entry for the 2001 Gordon Bell Award in the "special" category, we describe our 3-d, hybrid, adaptive mesh refinement (AMR) code Enzo designed for high-resolution, multiphysics, cosmological structure formation simulations. Our parallel implementation places no limit on the depth or complexity of the adaptive grid hierarchy, allowing us to achieve unprecedented spatial and temporal dynamic range. We report on a simulation of primordial star formation which develops over 8000 subgrids at 34 levels of refinement to achieve a local refinement of a factor of 1012 in space and time. This allows us to resolve the properties of the first stars which form in the universe assuming standard physics and a standard cosmological model. Achieving extreme resolution requires the use of 128-bit extended precision arithmetic (EPA) to accurately specify the subgrid positions. We describe our EPA AMR implementation on the IBM SP2 Blue Horizon system at the San Diego Supercomputer Center.http://dx.doi.org/10.1155/2002/423041
collection DOAJ
language English
format Article
sources DOAJ
author Greg L. Bryan
Tom Abel
Michael L. Norman
spellingShingle Greg L. Bryan
Tom Abel
Michael L. Norman
Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation
Scientific Programming
author_facet Greg L. Bryan
Tom Abel
Michael L. Norman
author_sort Greg L. Bryan
title Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation
title_short Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation
title_full Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation
title_fullStr Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation
title_full_unstemmed Achieving Extreme Resolution in Numerical Cosmology Using Adaptive Mesh Refinement: Resolving Primordial Star Formation
title_sort achieving extreme resolution in numerical cosmology using adaptive mesh refinement: resolving primordial star formation
publisher Hindawi Limited
series Scientific Programming
issn 1058-9244
1875-919X
publishDate 2002-01-01
description As an entry for the 2001 Gordon Bell Award in the "special" category, we describe our 3-d, hybrid, adaptive mesh refinement (AMR) code Enzo designed for high-resolution, multiphysics, cosmological structure formation simulations. Our parallel implementation places no limit on the depth or complexity of the adaptive grid hierarchy, allowing us to achieve unprecedented spatial and temporal dynamic range. We report on a simulation of primordial star formation which develops over 8000 subgrids at 34 levels of refinement to achieve a local refinement of a factor of 1012 in space and time. This allows us to resolve the properties of the first stars which form in the universe assuming standard physics and a standard cosmological model. Achieving extreme resolution requires the use of 128-bit extended precision arithmetic (EPA) to accurately specify the subgrid positions. We describe our EPA AMR implementation on the IBM SP2 Blue Horizon system at the San Diego Supercomputer Center.
url http://dx.doi.org/10.1155/2002/423041
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AT tomabel achievingextremeresolutioninnumericalcosmologyusingadaptivemeshrefinementresolvingprimordialstarformation
AT michaellnorman achievingextremeresolutioninnumericalcosmologyusingadaptivemeshrefinementresolvingprimordialstarformation
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