TY - GEN
T1 - Submarine landslides on the upper southeast australian passive continental margin - Preliminary findings
AU - Clarke, Samantha
AU - Hubble, Thomas
AU - Airey, David
AU - Yu, Phyllis
AU - Boyd, Ron
AU - Keene, John
AU - Exon, Neville
AU - Gardner, James
PY - 2012
Y1 - 2012
N2 - The southeast Australian passive continental margin is narrow, steep and sediment-deficient, and characterized by relatively low rates of modern sedimentation. Upper slope (<1,200 m) sediments comprise mixtures of calcareous and terrigenous sand and mud. Three of twelve sediment cores recovered from geologically-recent, submarine landslides located offshore New South Wales/Queensland (NSW/QLD) are interpreted to have sampled failure surfaces at depths of between 85 and 220 cm below the present-day seabed. Differences in sediment physical properties are recorded above and below the three slide-plane boundaries. Sediment taken directly above the inferred submarine landslide failure surfaces and presumed to be postlandslide, returned radiocarbon ages of 15.8, 20.7 and 20.1 ka. The last two ages correspond to adjacent slide features, which are inferred to be consistent with their being triggered by a single event such as an earthquake. Slope stability models based on classical soil mechanics and measured sediment shear-strengths indicate that the upper slope sediments should be stable. However, multibeam sonar data reveal that many upper slope landslides occur across the margin and that submarine landsliding is a common process. We infer from these results that: (a) an unidentified mechanism regularly acts to reduce the shear resistance of these sediments to the very low values required to enable slope failure, and/or (b) the margin experiences seismic events that act to destabilise the slope sediments.
AB - The southeast Australian passive continental margin is narrow, steep and sediment-deficient, and characterized by relatively low rates of modern sedimentation. Upper slope (<1,200 m) sediments comprise mixtures of calcareous and terrigenous sand and mud. Three of twelve sediment cores recovered from geologically-recent, submarine landslides located offshore New South Wales/Queensland (NSW/QLD) are interpreted to have sampled failure surfaces at depths of between 85 and 220 cm below the present-day seabed. Differences in sediment physical properties are recorded above and below the three slide-plane boundaries. Sediment taken directly above the inferred submarine landslide failure surfaces and presumed to be postlandslide, returned radiocarbon ages of 15.8, 20.7 and 20.1 ka. The last two ages correspond to adjacent slide features, which are inferred to be consistent with their being triggered by a single event such as an earthquake. Slope stability models based on classical soil mechanics and measured sediment shear-strengths indicate that the upper slope sediments should be stable. However, multibeam sonar data reveal that many upper slope landslides occur across the margin and that submarine landsliding is a common process. We infer from these results that: (a) an unidentified mechanism regularly acts to reduce the shear resistance of these sediments to the very low values required to enable slope failure, and/or (b) the margin experiences seismic events that act to destabilise the slope sediments.
KW - Continental slope
KW - Mass-failure
KW - Multibeam
KW - Seafloor geomorphology
UR - http://www.scopus.com/inward/record.url?scp=84904131415&partnerID=8YFLogxK
U2 - 10.1007/978-94-007-2162-3_5
DO - 10.1007/978-94-007-2162-3_5
M3 - Conference contribution
SN - 9789400721616
T3 - Submarine Mass Movements and Their Consequences - 5th International Symposium
SP - 55
EP - 66
BT - Submarine Mass Movements and Their Consequences - 5th International Symposium
PB - Kluwer Academic Publishers
T2 - 5th International Symposium on Submarine Mass Movements and Their Consequences
Y2 - 24 October 2011 through 26 October 2011
ER -