GCS LARGE-SCALE PROJECTS

Large-scale projects and highly scalable parallel applications are characterised by large computing time requirements, not only for short time frames but often for longer time periods. Projects are currently classified as "large-scale", if they require at least 100 Mcore-h on Hawk, or 45,000 EFLOP on JUWELSor 45 Mcore-h on SuperMUC-NG. These values correspond to 2% of the systems’ annual production in terms of estimated availability. The call for GCS Large-Scale Projects is issued twice a year and approved projects start on 1 May and 1 November, respectively.

For an overview of approved GCS Large-Scale Projects, please chose from the list below.

GCS Large-Scale Projects, Call 28, 2022/2


Computing time period for all projects of this call: November 1, 2022 – October 31, 2023


At HLRS: 

  • “Regulation of Substrate Transport in the Early Stages of Fatty Acid Synthesis” 
    Principal Investigator: Prof. Helmut Grübmüller, Max Planck Institute for Mutlidisciplinary Sciences
    HPC platform: Hawk
     
  • “Lattice QCD with High Precision” (GCS-wprecision)
    Principal Investigator: Prof. Zoltán Fodor, University of Wuppertal
    HPC platform: Hawk
     
  • “Hadronic Contributions to the Anomalous Magnetic Moment of the Muon from Lattice QCD” (GCS-HQCD)
  • Principal Investigator: Prof. Hartmut Wittig, University of Mainz
    HPC platform: Hawk
     
  • “Investigation of Turbulence and Flow Control in Boundary Layers” (GCS-Lamt)
    Principal Investigator: Dr. Markus Kloker, University of Stuttgart
    HPC platform: Hawk
     
  • “Analysis of Wheel Space Sealing in Axial Turbines, Optimization of Chevron Nozzles and Active Drag Reduction” (spof)
    Principal Investigator: Dr. Matthias Meinke, RWTH Aachen University
    HPC platform: Hawk

At JSC: 

  • “Emulation of Hybrid Quantum-Classical Simulations” (ehqcs) 
    Principal Investigator: Prof. Kristel Michielsen, Forschungszentrum Jülich
    HPC platforms: JUWELS Booster and JUWELS Cluster
     
  • “Direct QCD Simulations at Finite Density” (signqcd) 
    Principal Investigator: Prof. Szabolcs Borsanyi, University of Wuppertal
    HPC platform: JUWELS Booster and JUWELS Cluster
     
  • “High-Precision Calculation of the Muon Anomalous Magnetic Moment with Chiral Fermions” (gm2dwf)
    Principal Investigator: Prof. Christoph Lehner, University of Regensburg
    HPC platform: JUWELS Booster
     
  • “Isospin Breaking Effects in QCD” (pn56bu)
    Principal Investigator: Prof. Kálmán Szabó, Forschungszentrum Jülich
    HPC platform: JUWELS Booster and SuperMUC-NG (LRZ)
     
  • “Flavour Singlet Structure of Hadrons” (fssh) 
    Principal Investigator: Prof. Carsten Urbach, University of Bonn
    HPC platform: JUWELS Booster
     
  • “Hadronic Interactions and Spectroscopy in Lattice QCD with Wilson Quarks” (hintspec) 
    Principal Investigator: Prof. Hatmut Wittig, University of Mainz
    HPC platforms. JUWELS Booster and JUWELS Cluster
     
  • “The Ultimate Turbulent Rotating Convection”
    Principal Investigator: Dr. Xiaojue Zhu, Max Planck Institute for Solar System Research
    HPC platform: JUWELS Booster
     
  • “Effect of Scale on Transfer and Robustness for Foundational Supervised and Self-Supervised Deep Learning Models”
    Principal Investigator: Dr. Jenia Jitsev, Forschungszentrum Jülich
    HPC platform. JUWELS Booster

At LRZ: 

  • “Numerical Renormalization Group Computation of Local Multipoint Correlation Functions” (pn25ze)
    Principal Investigator: Prof. Jan von Delft, Ludwigs Maximillians Universität München
    HPC platform: SuperMUC-NG
     
  • “Weak Decays of Beauty and Charm Mesons to Multi-Hadron Final States on the Lattice” (pr27yo)
    Principal Investigator: Dr. Marcus Petschlies, University of Bonn 
    HPC platform: SuperMUC-NG
     
  • “Isospin Breaking Effects in QCD” (pn56bu)
    Principal Investigator: Prof. Kálmán Szabó, Forschungszentrum Jülich
    HPC platform: SuperMUC-NG and JUWELS Booster (JSC)
     
  • “Convection in the Planetary Boundary Layer” (pn49de) 
    Principal Investigator: Prof. Juan Pedro Mellado, University of Hamburg
    HPC platform: SuperMUC-NG
     
  • “Magnetic Field Effects on the Laminar-Turbulent Transition in Three-Dimensional Duct Flows” (pn49su) 
    Principal Investigator: Dr. Thomas Boeck, Technical University of Illmenau
    HPC platform: SuperMUC-NG 
     
  • “DNS of a Turbulent Jet Flow at varying Co-Flow with a Passive Scalar Transport - Validation of the Symmetry-Based Turbulence Theory” (pn73fu)
    Principal Investigator: Prof. Martin Oberlack, Technical University of Darmstadt
    HPC platform: SuperMUC-NG
     
  • “Direct Numerical Simulations of Turbulent Premixed Hydrogen Flames with Thermo-Diffusive Instabilities at Different Reynolds and Karlowitz Numbers”
    Principal Investigator: Prof. Heinz Pitsch, RWTH Aachen University
    HPC platform: SuperMUC-NG
     
  • “High-Performance Methods for Large-Scale Phase-Field Simulations of Solid-State Sintering” 
    Principal Investigator: Dr. Vladimir Ivannikov, Helmholtz Zentrum Hereon
    HPC platform: SuperMUC-NG