We try to unravel the complex interplay of sub-surface processes in geological structures by means of novel numerical simulations, simultaneously considering wide ranging time and length scales from the rock pore to the scale of the earth’s crust.
Of particular interest is the migration of CO2 in geo-storage facilities, hydrocarbon pathways and flow and recovery from fractured reservoirs, as well as the discovery scale-aware constitutive relationships for heterogeneous porous media.
Simulation-based forecasting and monitoring of subsurface behaviour of carbon dioxide
Quantifying CO2 trapping mechanisms and capacity in open saline aquifers
Multiscale static and dynamic modelling of Precipice Facies, Wendoan, Surat Basin, Queensland
Simulation of flow, transport and mechanic processes in fractured rocks
Adaptive unstructured discretisation and fluid-flow property computations on segmented images of porous media
Our research approach: Simulation-Guided Complex Systems Engineering
- Simulation-Based Engineering Science
- Goal: predict system behaviour from sparse observations
- What-if? Analysis of natural and engineered systems
- Early detection and elimination of side effects of engineering measures
- Optimisation of system performance
- Assimilation of monitoring data
- Uncertainty analysis
- Cyber-physical systems
Complex systems modeling platform (CSMP++) etc.
- Goal-based simulation (space-time adaptive methods)
- HPC parallel cloud- / GPU / real-time computing
- Extensive international collaboration
- Industry consortia and champions in high-impact application areas (CTC)
- Development of commercial strength user-friendly software through strategic alliances with industry
- Impact illustrated by showcases and benchmarks that show that technology makes a difference