Abstract
Tsunamis are unpredictable events and catastrophic in their potential for destruction of human lives and economy. The unpredictability of their occurrence poses a challenge to the tsunami community, as it is difficult to obtain from the tsunamigenic records estimates of recurrence rates and severity. Accurate and efficient mathematical/computational modeling is thus called upon to provide tsunami forecasts and hazard assessments. Compounding this challenge for warning centres is the physical nature of tsunamis, which can travel at extremely high speeds in the open ocean or be generated close to the shoreline. Thus, tsunami forecasts must be not only accurate but also delivered under severe time constraints. In the immediate aftermath of a tsunamigenic earthquake event, there are uncertainties in the source such as location, rupture geometry, depth, magnitude. Ideally, these uncertainties should be represented in a tsunami warning. However in practice, quantifying the uncertainties in the hazard intensity (i.e.,maximum tsunami amplitude) due to the uncertainties in the source is not feasible, since it requires a large number of high resolution simulations. We approximate the functionally complex and computationally expensive high resolution tsunami simulations with a simple and cheap statistical emulator. A workflow integrating the entire chain of components from the tsunami source to quantification of hazard uncertainties is developed here - quantification of uncertainties in tsunamigenic earthquake sources, high resolution simulation of tsunami scenarios using the GPU version of Volna-OP2 on a non-uniform mesh for an ensemble of sources, construction of an emulator using the simulations as training data, and prediction of hazard intensities with associated uncertainties using the emulator. Thus, using the massively parallelized finite volume tsunami code Volna-OP2 as the heart of the workflow, we use statistical emulation to compute uncertainties in hazard intensity at locations of interest. Such an integration also balances the trade-off between computationally expensive simulations and desired accuracy of uncertainties, within given time constraints. The developed workflow is fully generic and independent of the source (1945 Makran earthquake) studied here.
Highlights
The 2004 Indian Ocean tsunami was the worst tsunami disaster in the world’s history (Satake, 2014)
Severe time constraints compound the difficulties faced by tsunami early warning centres in providing accurate tsunami wave forecasts
Tsunami early warning centres are responsible for detecting tsunamigenic sources and in this paper we focus on tsunamis triggered by earthquakes
Summary
The 2004 Indian Ocean tsunami was the worst tsunami disaster in the world’s history (Satake, 2014). A more involved approach incorporates the large databases of pre-computed tsunami simulations from identified sources that most tsunami warning centres possess for their respective regions. In the immediate aftermath of an earthquake event there is always some uncertainty associated with the characteristic features of the seismic source At present, these uncertainties are not fully accounted for in traditional tsunami early warning approaches. The second type involves the maximum tsunami wave heights with associated uncertainties generated using the emulator These are presented for various output locations – points along a coastline at a fixed depth, localized maps and regional maps. The paper is wrapped up with concluding remarks and future work (section 7)
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