Octo-Tiger Awarded Access to the World鈥檚 Fastest Supercomputer

A density slice from a simulation of a merging contact binary system, viewing it just before the system merges. The color indicates how dense the gas is in the midplane, with brown indicating the densest gas and blue the least dense.

Researchers who recently developed 鈥�Octo-Tiger,鈥� a breakthrough astrophysics code that simulates the evolution of star systems, have been granted access to the supercomputer Fugaku in Tokyo.

Announced by The Research Organization for Information Science and Technology, researchers from 海角社区 and the University of Stuttgart have been awarded resources to test the Octo-Tiger code on Fugaku, exploring the novel architecture and benefiting from the world鈥檚 fastest supercomputer, to progress large simulations more expediently and possibly at a higher resolution.

鈥淭his is a great opportunity for Octo-Tiger to be able to run large simulations even faster than previously experienced,鈥� said Patrick Diehl, researcher, 海角社区 Center of Computation & Technology.

Developed from a unique collaboration between experimental computer scientists and astrophysicists, the Octo-Tiger code models stellar collisions more expeditiously than the established code used for numerical simulations.

Project members for the Fugaku Access Project include research scientists Patrick Diehl, Hartmut Kaiser and Dominic C. Marcello, ; postdoctoral researcher Sagiv Shiber, 海角社区 Department of Physics & Astronomy; and researcher Gregor Daiss, .

鈥淭hanks to the awarding of resources to access Fugaku, we will be able to substantially reduce the computational time to complete a simulation with Octo-Tiger,鈥� said Shiber

Octo-Tiger is currently optimized to simulate the merger of well-resolved stars that can be approximated by barotropic structures, such as white dwarfs or main sequence stars. The gravity solver conserves angular momentum to machine precision, thanks to a correction algorithm. This code uses HPX parallelization, allowing the overlap of work and communication and leading to excellent scaling properties to solve large problems in shorter time frames.

Published in , 鈥�,鈥� investigates the code performance and precision through benchmark testing. The authors, Marcello, Shiber, Diehl, Kaiser and 海角社区 Professors Juhan Frank and Geoffrey C. Clayton鈥攖ogether with collaborators Dr. Orsola De Marco, professor at Macquarie University, Sydney, Australia and Dr. Patrick M. Motl, professor at Indiana University Kokomo鈥攃ompared their results to analytic solutions, when known, and other grid-based codes, such as the popular FLASH. In addition, they computed the interaction between two white dwarfs from the early mass transfer through to the merger and compared the results with past simulations of similar systems.

The research outlines the current and planned areas of development aimed at tackling several physical phenomena connected to observations of transients.

The supercomputer Fugaku, jointly developed by RIKEN and Fujitsu since 2014, was completed on March 9, 2021. On the same day, Fugaku became available for shared use, providing access for a wide range of researchers and users in academic and industrial fields.

View the animation here

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Contact:

Mimi LaValle

海角社区 Department of Physics & Astronomy

225-439-5633

mlavall@lsu.edu