GCS Large-Scale Projects, Call 27 (February 2022) Gauss Centre for Supercomputing e.V.

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.

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

GCS Large-Scale Projects, Call 27 (February 2022)


Computing time period for all projects of this call: May 1, 2022 – April 30, 2023


at HLRS: 

  • Bulk features of the quark gluon plasma at finite density
    Principal Investigator: Prof. Dr. Zoltán Fodor, University of Wuppertal
    HPC platform: Hawk
     
  • Simulation of multiphase flow in pECM, self/cross-attention based deep optical flow estimation, thermoacoustic analysis of hydrogen-air flames, and model formulations for non-spherical particles 
    Principal Investigator: Dr. Matthias Meinke, RWTH Aachen 
    HPC platform: Hawk

at JSC: 

  • Spectrally-resolved radiation skymaps of PWFA plasma instabilities
    Principal Investigator: Dr. Alexander Debus, Helmholtz Zentrum Dresden-Rossendorf
    HPC platform: JUWELS Booster and JUWELS Cluster
     
  • State-of-the-art lattice QCD simulation for hadron structure
    Principal Investigator: Dr. Karl Jansen, Deutsches Elektronen Synchotron
    HPC platform: JUWELS Booster
     
  • Nuclear Lattice Simulations
    Principal Investigator: Prof. Dr. Ulf-G. Meißner, Forschungszentrum Jülich 
    HPC platform: JUWELS Booster and JUWELS Cluster
     
  • The role of low collisionality in compressible, magnetized turbulence
    Principal Investigator: Dr. Philipp Grete, Universität Hamburg
    HPC platform: JUWELS Booster and JUWELS Cluster
     
  • Multi-scale Data-driven Engine Modeling Using Direct Numerical Simulations
    Principal Investigator: Mathis Bode, Forschungszentrum Jülich
    HPC platform: JUWELS Booster and JUWELS Cluster
     
  • Simulation of multiphase flow in pECM, self/cross-attention based deep optical flow estimation, thermoacoustic analysis of hydrogen-air flames, and model formulations for non-spherical particles
    Principal Investigator: Dr. Matthias Meinke, RWTH Aachen 
    HPC platform: JUWELS Booster

at LRZ: 

  • Emergent and critical phenomena in correlated electron systems: Quantum Monte Carlo simulations
    Principal Investigator: Prof. Dr. Fakher Assad, Univeristät Würzburg
    HPC plaform: SuperMUC-NG
     
  • Heat flux regulation by collisionless processes in heliospheric plasmas
    Principal Investigator: Prof. Dr. Maria Elena Innocenti, Ruhr Universität Bochum 
    HPC platform: SuperMUC-NG 
     
  • State-of-the-art lattice QCD simulation for hadron structure
    Principal Investigator: Dr. Karl Jansen, Deutsches Elektronen Synchrotron
    HPC platform: SuperMUC-NG
     
  • Charmonium and Confinement from Lattice QCD
    Principal Investigator: Prof. Dr. Francesco Knechtli, Bergische Universität Wuppertal
    HPC platform: SuperMUC-NG
     
  • Flavor-singlet meson physics from lattice QCD
    Principal Investigator: Prof. Dr. Kalman Szabo, Forschungszentrum Jülich
    HPC platform: SuperMUC-NG
     
  • Form factors of pseudoscalar mesons with Lattice QCD
    Principal Investigator: Prof. Dr. Georg von Hippel, Johannes Gutenberg Universität Mainz 
    HPC platform: SuperMUC-NG
     
  • The Local Universe: Galaxies, Clusters, The LSS and Cosmic Rays
    Principal Investigator: Dr. Klaus Dolag, Ludwig-Maximillians-Universität München
    HPC platform: SuperMUC-NG
     
  • The Fate of Cold Clouds in Galactic Winds
    Principal Investigator: Dr. Ryan Farber, Max Planck Gesellschaft
    HPC platform: SuperMUC-NG
     
  • Intrinsic instability and NOx formation in 3D thermodiffusively unstable premixed hydrogen flames
    Principal Investigator: Prof. Dr. Heinz Pitsch, RWTH Aachen
    HPC platform: SuperMUC-NG
     
  • Thermal Turbulence at Extreme Rayleigh Numbers
    Principal Investigator: Prof. Dr. Detlef Lohse, Max Planck Gesellschaft 
    HPC platform: SuperMUC-NG