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 JUWELS, or 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 30, 2023/2
Computing time period for all projects of this call: November 1, 2023 - October 31, 2024
At HLRS:
“Muon magnetic moment”
Prof. Zoltán Fodor, Bergische Universität Wuppertal
HPC platform: Hawk
“Hadronic contributions to the anomalous magnetic moment of the muon from Lattice QCD”
Prof. Hartmut Wittig, Universität Mainz
HPC platform: Hawk
„ Advanced aerodynamic, aeroelastic and aeroacoustic simulation of rotorcraft”
Dr. Manuel Keßler, Universität Stuttgart
HPC platform: Hawk
“Mixing in Internal Combustion Engines and Active Drag Reduction”
Dr. Matthias Meinke, RWTH Aachen
HPC platform: Hawk and JUWELS Booster
“Analysis of wheel space sealing flow in turbine stages and aeroacoustics of propeller-airfoil interaction”
Dr. Matthias Meinke, RWTH Aachen
HPC platform: Hawk
“Investigation of Turbulence and Flow Control in Boundary Layers”
Dr. Christoph Wenzel, Universität Stuttgart
HPC platform: Hawk
At JSC:
“Emulation of hybrid quantum-classical simulations”
Prof. Kristel Michielsen, Forschungszentrum Jülich GmbH
HPC platform: JUWELS Booster and JUWELS CPU
“Towards the hot nuclear equation of state”
Prof. Szabolcs Borsányi, Bergische Universität Wuppertal
HPC platform: JUWELS Booster and JUWELS GPU
“High-precision calculation of the muon anomalous magnetic moment with chiral fermions”
Prof. Christoph Lehner, Universität Regensburg
HPC platform: JUWELS Booster
“Pion-nucleon excited state effects in extracting nucleon observables from lattice QCD”
Dr. Marcus Petschlies, Universität Bonn
HPC platform: JUWELS Booster
“Advanced hadron spectroscopy in lattice QCD”
Prof. Kálmán Szabó, Forschungszentrum Jülich GmbH
HPC platform: JUWELS Booster and SuperMUC-NG
“Inclusive semileptonic decay rates from lattice QCD”
Prof. Carsten Urbach, Universität Bonn
HPC platform: JUWELS Booster
“Running couplings at the Z-boson mass”
Dr. Chik Him Wong, Bergische Universität Wuppertal
HPC platform: JUWELS Booster
“Collective Dynamics of Intelligent Microswimmers”
Prof. Gerhard Gompper, Forschungszentrum Jülich GmbH
HPC platform: JUWELS Booster
“Atmospheric Boundary Layer study using Large Eddy Simulations”
Mathis Bode, Forschungszentrum Jülich GmbH
HPC platform: JUWELS Booster and JUWELS CPU
“Deep Learning for Air Quality and Climate Forecasts”
PD Dr. Martin Schultz, Forschungszentrum Jülich GmbH
HPC platform: JUWELS Booster, JUWELS CPU and JUWELS GPU
“The ultimate turbulent rotating convection”
Dr. Xiaojue Zhu, Max-Planck Gesellschaft
HPC platform: JUWELS Booster
“Scaling laws for transferable language-vision learning with contrastive and generative components”
Dr. Jenia Jitsev, Forschungszentrum Jülich GmbH
HPC platform: JUWELS Booster
At LRZ:
“Numerical renormalization group computation of local multipoint correlation functions”
Prof. Jan von Delft, Ludwig Maximilians Universität München
HPC platform: SuperMUC-NG
“Weak decays of beauty and charm mesons to multi-hadron final states on the lattice”
Dr. Marcus Petschlies, Universität Bonn
HPC platform: SuperMUC-NG
“Advanced hadron spectroscopy in lattice QCD”
Prof. Kálmán Szabó, Forschungszentrum Jülich GmbH
HPC platform: SuperMUC-NG and JUWELS Booster
“The Local Universe: Galaxies, Clusters, The LSS and Cosmic Rays”
Dr. Klaus Dolag, Ludwig Maximilians Universität München
HPC platform: SuperMUC-NG
“Convection in the Planetary Boundary Layer”
Prof. Juan Pedro Mellado, Universität Hamburg
HPC platform: SuperMUC-NG
“Direct Numerical Simulations of Thermo-Diffusively Instable Turbulent Premixed Ammonia/Hydrogen/Air Flame”
Prof. Heinz Pitsch, RWTH Aachen
HPC platform: SuperMUC-NG