SubsidieMeestersKARST: Predicting flow and transport in complex Karst systems
KARST aims to develop advanced stochastic modeling frameworks to predict flow and transport in karst aquifers, enhancing understanding of their vulnerability to extreme flooding and contaminants.
Projectdetails
Introduction
Karst aquifers are a treasure and a threat: while up to 25% of the world population depends on them for drinking water, they also have capabilities for extremely fast conduction of water and contaminants. In the light of climate change, we need to prepare for extreme flooding and understand the consequences for karst aquifers.
Challenges in Assessment
Despite their socio-economic importance, decades of research, and high-profile disasters, karst structures and processes remain notoriously difficult to assess. Because of the complexity of karst and its lack of accessibility, the foundations of flow and transport modeling in karst systems are weak.
Key phenomena related to extreme events such as flash floods and heavy tails in tracer recovery are still beyond current modeling capabilities.
Objectives of the KARST Project
KARST will establish the next generation of coupled stochastic modeling frameworks to predict karst processes, assess the vulnerability of karst aquifers, and forecast their response to extreme events. Our approach will bridge structures and processes on all scales, far beyond the capabilities of current theories and computer simulations.
This will be achieved by targeting three key objectives:
- Identification and quantification of flow and transport dynamics at the conduit scale.
- Characterization and modeling of karst network structure at the catchment scale.
- Derivation of a new upscaled approach to predict karst processes at different resolution scales.
Together, this will result in an unprecedented multiscale modeling framework for the prediction of flow and transport in karst.
Synergy of the KARST PI Team
Solving this long-standing problem is possible thanks to the synergy of the KARST PI team, combining the set of skills and knowledge (hydrogeology, physics, mathematics) required to make a groundbreaking step in this field.
Broader Impact
Beyond that, the new approach is expected to impact other real-world systems in:
- Medicine (capillary networks)
- Neuroscience (brain microcirculation)
- Glaciology (meltwater flow in glaciers)
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 9.884.611 |
| Totale projectbegroting | € 9.884.611 |
Tijdlijn
| Startdatum | 1-5-2023 |
| Einddatum | 30-4-2029 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- AGENCIA ESTATAL CONSEJO SUPERIOR DE INVESTIGACIONES CIENTIFICASpenvoerder
- IFP Energies nouvelles
- UNIVERZA V LJUBLJANI
- UNIVERSITE DE NEUCHATEL
- Simon Fraser University
- INSTITUT NATIONAL DE RECHERCHE EN INFORMATIQUE ET AUTOMATIQUE
Land(en)
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