2020
DOI: 10.1007/s10346-020-01429-z
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On the landslide tsunami uncertainty and hazard

Abstract: Landslides are the second most frequent tsunami source worldwide. However, their complex and diverse nature of origin combined with their infrequent event records make prognostic modelling challenging. In this paper, we present a probabilistic framework for analysing uncertainties emerging from the landslide source process. This probabilistic framework employs event trees and is used to conduct tsunami uncertainty analysis as well as probabilistic tsunami hazard analysis (PTHA). An example study is presented f… Show more

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Cited by 59 publications
(39 citation statements)
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“…Landslide tsunami PTHA (LPTHA) was introduced less than a decade ago (Geist and Lynett, 2014). Its application is often similar to SPTHA (e.g., ten Brink et al, 2006;Lane et al, 2016), but can also be based on geotechnical interpretations with a strong emphasis on expert judgment (e.g., Grilli et al, 2009;Hermanns et al, 2013;Løvholt et al, 2020). Salamon and Di Manna (2019) derive empirical scaling relations for landslides triggered by onshore earthquakes.…”
Section: Existing Methodsmentioning
confidence: 99%
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“…Landslide tsunami PTHA (LPTHA) was introduced less than a decade ago (Geist and Lynett, 2014). Its application is often similar to SPTHA (e.g., ten Brink et al, 2006;Lane et al, 2016), but can also be based on geotechnical interpretations with a strong emphasis on expert judgment (e.g., Grilli et al, 2009;Hermanns et al, 2013;Løvholt et al, 2020). Salamon and Di Manna (2019) derive empirical scaling relations for landslides triggered by onshore earthquakes.…”
Section: Existing Methodsmentioning
confidence: 99%
“…This can be done using landslide run-out information alone (e.g., Salmanidou et al, 2017), which consequently yields broad epistemic uncertainties in LPTHA. By using tsunami information, such uncertainties can be drastically reduced (e.g., Gylfadóttir et al, 2017;Kim et al, 2019;Løvholt et al, 2020). In practice, however, very few landslide tsunami data are available.…”
Section: Limited Past Events To Inform Hazard Models (L5)mentioning
confidence: 99%
“…Among all tsunamigenic earthquakes, the "tsunami earthquakes" deserve particular attention since they generate larger tsunamis than expected given their seismic moment magnitude, and both their mechanical process and frequency of occurrence are not completely understood [15]. Atypical sources also include all the other non-seismic tsunamigenic sources like sub-aerial near-coast and submarine landslides, a wide range of volcanic phenomena occurring both during eruptions or in non-eruptive periods (pyroclastic flows-fast currents of hot gas and volcanic materials, submarine explosions, caldera collapses, and flank instability are the most important ones), and meteotsunamis-tsunamis generated by atmospheric pressure disturbances (e.g., [16][17][18][19][20][21][22]).…”
Section: Introductionmentioning
confidence: 99%
“…Also this field is indeed a field of intense research activity [11,31,54,63,[90][91][92], and it is particularly challenging when extending to the large variety of atypical tsunami sources (e.g. [11,17,32,54]).…”
Section: Introductionmentioning
confidence: 99%
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