Massively-parallel Lagrangian particle code and applications

Massively-parallel, distributed-memory algorithms for the Lagrangian particle hydrodynamic method (Samulyak et al., 2018) have been developed, verified, and implemented. The key component of parallel algorithms is a particle management module that includes a parallel construction of octree databases...

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Vydané v:Mechanics research communications Ročník 129; číslo C; s. 104075
Hlavní autori: Yuan, Shaohua, Aguilar, Mario Zepeda, Naitlho, Nizar, Samulyak, Roman
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: United States Elsevier Ltd 01.05.2023
Elsevier
Predmet:
Lagrangian particle method
Multiphase flows
Parallel algorithms
Parallel k-tree
Multiphase flows
Lagrangian particle method
Parallel algorithms
Parallel k-tree
ISSN:0093-6413, 1873-3972
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Abstract Massively-parallel, distributed-memory algorithms for the Lagrangian particle hydrodynamic method (Samulyak et al., 2018) have been developed, verified, and implemented. The key component of parallel algorithms is a particle management module that includes a parallel construction of octree databases, dynamic adaptation and refinement of octrees, and particle migration between parallel subdomains. The particle management module is based on the p4est (parallel forest of k-trees) library. The massively-parallel Lagrangian particle code has been applied to a variety of fundamental science and applied problems. A summary of Lagrangian particle code applications to the injection of impurities into thermonuclear fusion devices and to the simulation of supersonic hydrogen jets in support of laser-plasma wakefield acceleration research has also been presented. •Massively-parallel, distributed-memory algorithms for Lagrangian particle method.•Particle manager based on parallel construction and dynamic adaptation of octrees.•Optimal load balance and good scalability on hundreds of cores.•Summary of applications to thermonuclear fusion and supersonic hydrogen jets.
AbstractList Massively-parallel, distributed-memory algorithms for the Lagrangian particle hydrodynamic method (Samulyak et al., 2018) have been developed, verified, and implemented. The key component of parallel algorithms is a particle management module that includes a parallel construction of octree databases, dynamic adaptation and refinement of octrees, and particle migration between parallel subdomains. The particle management module is based on the p4est (parallel forest of k-trees) library. The massively-parallel Lagrangian particle code has been applied to a variety of fundamental science and applied problems. A summary of Lagrangian particle code applications to the injection of impurities into thermonuclear fusion devices and to the simulation of supersonic hydrogen jets in support of laser-plasma wakefield acceleration research has also been presented. •Massively-parallel, distributed-memory algorithms for Lagrangian particle method.•Particle manager based on parallel construction and dynamic adaptation of octrees.•Optimal load balance and good scalability on hundreds of cores.•Summary of applications to thermonuclear fusion and supersonic hydrogen jets.
ArticleNumber 104075
Author Yuan, Shaohua
Aguilar, Mario Zepeda
Naitlho, Nizar
Samulyak, Roman
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  surname: Yuan
  fullname: Yuan, Shaohua
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  givenname: Mario Zepeda
  surname: Aguilar
  fullname: Aguilar, Mario Zepeda
  organization: Department of Applied Mathematics and Statistics, Stony Brook University, Stony Brook, NY 11794, USA
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  givenname: Roman
  orcidid: 0000-0002-1855-7400
  surname: Samulyak
  fullname: Samulyak, Roman
  email: roman.samulyak@stonybrook.edu
  organization: Department of Applied Mathematics and Statistics, Stony Brook University, Stony Brook, NY 11794, USA
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Snippet Massively-parallel, distributed-memory algorithms for the Lagrangian particle hydrodynamic method (Samulyak et al., 2018) have been developed, verified, and...
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SubjectTerms Lagrangian particle method
Multiphase flows
Parallel algorithms
Parallel k-tree
Title Massively-parallel Lagrangian particle code and applications
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https://www.osti.gov/biblio/1959269
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