Project description
So when’s the next earthquake?
Earthquakes are actually very common occurrences. They occur daily even though few people actually notice because they are phantom tremors (light and occur deeper underground). Only sensitive instruments can record them. What about predicting quakes or other destructive natural events like tsunamis. Is this possible? The EU-funded PERSISMO project may soon find out. It is building a physics-based Virtual Earthquake Simulator which will make seismic and tsunamic hazard estimates on fault networks. Specifically, it will create a framework that will include all known physical contributions to dynamic fracturing. The aim will be to unify a never-achieved range of spatiotemporal scales, from meters to hundreds of kilometres, seconds to millenniums.
Objective
Quantum leaps in observations have recently upended our classical view of earthquakes & tsunamis and have demonstrated that our understanding of these destructive natural events is not unified and still too limited to perform reliable predictions. Fortunately, catastrophic events remain relatively rare. Yet this scarcity also implies that their fine scale and long-term dynamics can only be studied in detail through numerical simulations.
The goal of PERSISMO is to build a physics based Virtual Earthquake Simulator to make seismic and tsunami hazard estimates on fault networks. Indeed, the modern view emanating from observations is that fault networks continuously release stored energy over a wide range of spatiotemporal scales. With this philosophy in mind, we have been developing simulation tools to capture the behaviour of these fault networks and our recent work has demonstrated that these networks indeed control the dominant portion of the continuous energy release, whatever the time and length scales considered.
Within PERSISMO, we will build a physics-based framework, which will include all known physical contributions to dynamic fracturing. This will unify a never achieved range of spatiotemporal scales, from meters to hundreds of kilometres, seconds to millenniums. Using available data and catalogues, our results will be validated along natural fault networks to capture slow and fast seismic energy release. Building on this, we will develop a Machine Learning based framework to run thousands of ensemble and future hazard scenarios on a given fault network. Only then, we might be able to make reliable predictions about their behaviour in the future.
Our project to build a physics-driven Virtual Earthquake Simulator is interdisciplinary by nature, as it must combine expertise in mechanics, earth sciences and computation. In the long-term, our simulator will have the potential to become key in helping decision makers on possible natural hazard scenarios.
Fields of science
- natural sciencesearth and related environmental sciencesgeologyseismology
- natural sciencesearth and related environmental sciencesphysical geographynatural disasters
- natural sciencescomputer and information sciencesartificial intelligencemachine learning
- natural sciencescomputer and information sciencessoftwaresoftware applicationssimulation software
- humanitiesphilosophy, ethics and religionphilosophy
Programme(s)
Funding Scheme
ERC-COG - Consolidator GrantHost institution
75794 Paris
France