Fluid Dynamics & Flow
Resolving the AMOC and sub-mesoscale eddies through advanced petascale CFD solvers.
Engineering Global Ventilation
The ocean is the planet's primary thermal regulator. Resolving the Atlantic Meridional Overturning Circulation (AMOC) and the 10km-scale sub-mesoscale eddies requires an unprecedented level of computational granularity. Malgukke provides the Petascale CFD orchestration needed to simulate salinity and heat transfer, predicting the stability of global ventilation systems.
Thermohaline Circulation
Simulating salinity and heat transfer to predict global ventilation systems. We model the complex density-driven currents that act as the Earth's conveyor belt, ensuring accurate forecasting of oceanic heat storage and transport.
- Density-driven flow modeling
- Deep-water formation simulations
Sub-mesoscale Eddies
Resolving 10km-scale Arctic eddies that modulate heat transport and nutrient distribution. Our HPC solvers allow for the localized nesting of high-resolution grids within global models to capture the energy exchange of mesoscale vortices.
- Eddy-resolving ocean models (EROM)
- Convective-scale vortex tracking
World-Class Ocean Research Partners
Malgukke’s high-performance infrastructure powers the break-through research of these global leaders:
Fluid Dynamics Pipeline
| Dynamic System | HPC / Action | Climatological Outcome |
|---|---|---|
| Atlantic AMOC | Multi-physics coupling of salinity and thermal flux. | Stability verification of the European climate |
| Arctic Vortex | GPU-accelerated Navier-Stokes solvers at sub-10km scale. | Quantified ice-melt acceleration rates |