Timing and frequency of large submarine landslides: implications for understanding triggers and future geohazard
Timing and frequency of large submarine landslides: implications for understanding triggers and future geohazard
Large submarine landslides can have serious socioeconomic consequences as they have the potential to cause tsunamis and damage seabed infrastructure. It is important to understand the frequency of these landslides, and how that frequency is related to climate-driven factors such as sea level or sedimentation rate, in order to assess their occurrence in the future. Recent studies have proposed that more landslides occur during periods of sea level rise and lowstand, or during periods of rapid sedimentation. In this contribution we test these hypotheses by analysing the most comprehensive global data set of ages for large (>1 km3) late Quaternary submarine landslides that has been compiled to date. We include the uncertainties in each landslide age that arise from both the dating technique, and the typically larger uncertainties that result from the position of the samples used for dating. Contrary to the hypothesis that continental slope stability is linked to sea level change, the data set does not show statistically significant patterns, trends or clusters in landslide abundance. If such a link between sea level and landslide frequency exists it is too weak to be detected using the available global data base. It is possible that controlling factors vary between different geographical areas, and their role is therefore hidden in a global data set, or that the uncertainties within the dates is too great to see an underlying correlation. Our analysis also shows that there is no evidence for an immediate influence of rapid sedimentation on slope stability as failures tend to occur several thousand years after periods of increased sedimentation rates. The results imply that there is not a strong global correlation of landslide frequency with sea level changes or increases in local sedimentation rate, based on the currently available ages for large submarine landslides.
Submarine landslides, Sea level, Tsunami, Timing
63-82
Urlaub, Morelia
f5a21932-9794-4008-b0a9-72bb366098b8
Talling, Peter J.
1cbac5ec-a9f8-4868-94fe-6203f30b47cf
Masson, Doug G.
edd44c8b-38ca-45fb-8d0d-ac8365748a45
15 July 2013
Urlaub, Morelia
f5a21932-9794-4008-b0a9-72bb366098b8
Talling, Peter J.
1cbac5ec-a9f8-4868-94fe-6203f30b47cf
Masson, Doug G.
edd44c8b-38ca-45fb-8d0d-ac8365748a45
Urlaub, Morelia, Talling, Peter J. and Masson, Doug G.
(2013)
Timing and frequency of large submarine landslides: implications for understanding triggers and future geohazard.
Quaternary Science Reviews, 72, .
(doi:10.1016/j.quascirev.2013.04.020).
Abstract
Large submarine landslides can have serious socioeconomic consequences as they have the potential to cause tsunamis and damage seabed infrastructure. It is important to understand the frequency of these landslides, and how that frequency is related to climate-driven factors such as sea level or sedimentation rate, in order to assess their occurrence in the future. Recent studies have proposed that more landslides occur during periods of sea level rise and lowstand, or during periods of rapid sedimentation. In this contribution we test these hypotheses by analysing the most comprehensive global data set of ages for large (>1 km3) late Quaternary submarine landslides that has been compiled to date. We include the uncertainties in each landslide age that arise from both the dating technique, and the typically larger uncertainties that result from the position of the samples used for dating. Contrary to the hypothesis that continental slope stability is linked to sea level change, the data set does not show statistically significant patterns, trends or clusters in landslide abundance. If such a link between sea level and landslide frequency exists it is too weak to be detected using the available global data base. It is possible that controlling factors vary between different geographical areas, and their role is therefore hidden in a global data set, or that the uncertainties within the dates is too great to see an underlying correlation. Our analysis also shows that there is no evidence for an immediate influence of rapid sedimentation on slope stability as failures tend to occur several thousand years after periods of increased sedimentation rates. The results imply that there is not a strong global correlation of landslide frequency with sea level changes or increases in local sedimentation rate, based on the currently available ages for large submarine landslides.
This record has no associated files available for download.
More information
Published date: 15 July 2013
Keywords:
Submarine landslides, Sea level, Tsunami, Timing
Organisations:
Geology & Geophysics, Marine Geoscience
Identifiers
Local EPrints ID: 355673
URI: http://eprints.soton.ac.uk/id/eprint/355673
ISSN: 0277-3791
PURE UUID: 9fde0efc-3cca-434e-9989-b3519e645c0c
Catalogue record
Date deposited: 12 Aug 2013 10:31
Last modified: 14 Mar 2024 14:35
Export record
Altmetrics
Contributors
Author:
Morelia Urlaub
Author:
Peter J. Talling
Author:
Doug G. Masson
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics