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The AGORA High-Resolution Galaxy Simulations Comparison Project. II: Isolated Disk Test

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arxiv 1610.03066 v4 pith:5HLWKTWW submitted 2016-10-10 astro-ph.GA astro-ph.CO

The AGORA High-Resolution Galaxy Simulations Comparison Project. II: Isolated Disk Test

Ji-hoon Kim (1 , 2 , 3 , 4) , Oscar Agertz (5 , 6) , Romain Teyssier (7) , Michael J. Butler (8)
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Daniel Ceverino (9) Jun-Hwan Choi (10) Robert Feldmann (7 11) Ben W. Keller (12) Alessandro Lupi (13) Thomas Quinn (14) Yves Revaz (15) Spencer Wallace (14) Nickolay Y. Gnedin (16 17 18) Samuel N. Leitner (19) Sijing Shen (20) Britton D. Smith (21) Robert Thompson (22) Matthew J. Turk (23) Tom Abel (1 2) Kenza S. Arraki (24) Samantha M. Benincasa (12) Sukanya Chakrabarti (25) Colin DeGraf (20) Avishai Dekel (26) Nathan J. Goldbaum (22) Philip F. Hopkins (3) Cameron B. Hummels (3) Anatoly Klypin (24) Hui Li (27) Piero Madau (28 13) Nir Mandelker (29 26) Lucio Mayer (7) Kentaro Nagamine (30 31) Sarah Nickerson (7) Brian W. O'Shea (32) Joel R. Primack (1) Santi Roca-F\`abrega (26) Vadim Semenov (17) Ikkoh Shimizu (30) Christine M. Simpson (33) Keita Todoroki (34) James W. Wadsley (12) John H. Wise (35) (for the AGORA Collaboration) ((1) Kavli Institute for Particle Astrophysics Cosmology SLAC National Accelerator Laboratory (2) Stanford University (3) California Institute of Technology (4) Einstein Fellow (5) University of Surrey (6) Lund University (7) University of Zurich (8) Max-Planck-Institut f\"ur Astronomie (9) Zentrum f\"ur Astronomie der Universit\"at Heidelberg Institut f\"ur Theoretische Astrophysik (10) University of Texas Austin (11) University of California at Berkeley (12) McMaster University (13) Sorbonne Universites UPMC Univ Paris 6 et CNRS (14) University of Washington Seattle (15) \'Ecole Polytechnique F\'ed\'erale de Lausanne (16) Fermi National Accelerator Laboratory (17) University of Chicago (18) Kavli Institute for Cosmological Physics (19) University of Maryland (20) University of Cambridge (21) University of Edinburgh (22) National Center for Supercomputing Applications (23) University of Illinois Urbana (24) New Mexico State University (25) Rochester Institute of Technology (26) The Hebrew University (27) University of Michigan Ann Arbor (28) University of California at Santa Cruz (29) Yale University (30) Osaka University (31) University of Nevada Las Vegas (32) National Superconducting Cyclotron Laboratory Michigan State University (33) Heidelberger Institut f\"ur Theoretische Studien (34) University of Kansas (35) Georgia Institute of Technology)
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classification astro-ph.GA astro-ph.CO
keywords commondensitydiskgalaxynumericalphysicscodesdifferences
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Using an isolated Milky Way-mass galaxy simulation, we compare results from 9 state-of-the-art gravito-hydrodynamics codes widely used in the numerical community. We utilize the infrastructure we have built for the AGORA High-resolution Galaxy Simulations Comparison Project. This includes the common disk initial conditions, common physics models (e.g., radiative cooling and UV background by the standardized package Grackle) and common analysis toolkit yt, all of which are publicly available. Subgrid physics models such as Jeans pressure floor, star formation, supernova feedback energy, and metal production are carefully constrained across code platforms. With numerical accuracy that resolves the disk scale height, we find that the codes overall agree well with one another in many dimensions including: gas and stellar surface densities, rotation curves, velocity dispersions, density and temperature distribution functions, disk vertical heights, stellar clumps, star formation rates, and Kennicutt-Schmidt relations. Quantities such as velocity dispersions are very robust (agreement within a few tens of percent at all radii) while measures like newly-formed stellar clump mass functions show more significant variation (difference by up to a factor of ~3). Systematic differences exist, for example, between mesh-based and particle-based codes in the low density region, and between more diffusive and less diffusive schemes in the high density tail of the density distribution. Yet intrinsic code differences are generally small compared to the variations in numerical implementations of the common subgrid physics such as supernova feedback. Our experiment reassures that, if adequately designed in accordance with our proposed common parameters, results of a modern high-resolution galaxy formation simulation are more sensitive to input physics than to intrinsic differences in numerical schemes.

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