These seven real-world HPC applications play a crucial role in our research. Their requirements for both the hardware and system software/API aspects drive the co-design process: The selected applications are continuously optimized for the Cluster/Booster architecture, the CPU and innovative network technologies used. This results in a system that fits the needs of the applications, and showcases that demonstrate the efficiency and performance of the DEEP-ER machine.

The assessment of the possible health effects linked to the exposure of humans to electromagnetic fields emitted from wireless systems is of particular interest to the well-being in our modern society.

The Square Kilometre Array (SKA), the next-generation radio telescope has Exascale compute requirements.

The research field aims at understanding the physical processes of large scale geological incidents (e.g. earthquakes) and their secondary effects (e.g. tsunamis).

Full Waveform Inversion is a technique that allows to probe the physical properties of a subsurface area with high spatial resolution using seismic data.

Lattice QCD (Quantum Chromodynamics) studies the fundamental theory of the strong interactions numerically and has been at the forefront of HPC since the 1980s.

Towards exascale simulations of space plasmas using the DEEP-ER architecture.

The understanding of superconducting mechanisms in high critical temperature (HTc) materials (such as copper oxides) remains one of the most challenging topics in condensed matter physics.