SUBMARINE LANDSLIDES

Liquefied submarine sediments can easily lead to submarine landslides and turbidity currents, and cause serious damage to offshore engineering facilities. Understanding the rheological characteristics of liquefied sediments is critical for improving our knowledge of the prevention of submarine geo-hazards and the evolution of submarine topography. In this study, an in situ test device was developed to measure the rheological properties of liquefied sediments. The test principle is the shear column theory. The device was tested in the subaqueous Yellow River delta, and the test results indicated that liquefied sediments can be regarded as “non-Newtonian fluids with shear thinning characteristics”. Furthermore, a laboratory rheological test was conducted as a contrast experiment to qualitatively verify the accuracy of the in situ test data. Through the comparison of experiments, it was proved that the use of the in situ device in this paper is suitable and reliable for the measurement of the rheological characteristics of liquefied submarine sediments. Considering the fact that liquefaction may occur in deeper water (>5 m), a work pattern for the device in the offshore area is given. This novel device provides a new way to test the undrained shear strength of liquefied sediments in submarine engineering.

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On numerical modelling of impulse water waves generated by submarine landslides

Environmental Earth Sciences ◽

10.1007/s12665-015-4746-3 ◽

2015 ◽

Vol 74 (11) ◽

pp. 7387-7405 ◽

Cited By ~ 4

Author(s):

Nina Shokina ◽

Vadym Aizinger

Keyword(s):

Numerical Modelling ◽

Water Waves ◽

Submarine Landslides

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Simulation of tsunami waves generated by submarine landslides in the Black Sea

Russian Journal of Numerical Analysis and Mathematical Modelling ◽

10.1515/rnam-2015-0020 ◽

2015 ◽

Vol 30 (4) ◽

Cited By ~ 1

Author(s):

Gayaz S. Khakimzyanov ◽

Oleg I. Gusev ◽

Sofya A. Beizel ◽

Leonid B. Chubarov ◽

Nina Yu. Shokina

Keyword(s):

Surface Waves ◽

Black Sea ◽

Numerical Technique ◽

Submarine Landslide ◽

The Black Sea ◽

Submarine Landslides ◽

Hydrodynamic Approximation ◽

Tsunami Waves ◽

Dispersive Model ◽

Shallow Water Models

AbstractNumerical technique for studying surface waves appearing under the motion of a submarine landslide is discussed. This technique is based on the application of the model of a quasi-deformable landslide and two shallow water models, namely, the classic (dispersion free) one and the completely nonlinear dispersive model of the second hydrodynamic approximation. Numerical simulation of surface waves generated by a large model landslide on the continental slope of the Black Sea near the Russian coast is performed. It is shown that the dispersion has a significant impact on the picture of propagation of tsunami waves on sufficiently long paths.

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Stratigraphic and tectonic control of deep-water scarp accumulation in Paleogene synorogenic basins: a case study of the Súľov Conglomerates (Middle Váh Valley, Western Carpathians)

Geologica Carpathica ◽

10.1515/geoca-2017-0027 ◽

2017 ◽

Vol 68 (5) ◽

pp. 403-418 ◽

Cited By ~ 2

Author(s):

Ján Soták ◽

Zuzana Pulišová ◽

Dušan Plašienka ◽

Viera Šimonová

Keyword(s):

Deep Water ◽

Fault Scarp ◽

Submarine Landslides ◽

Orogenic Wedge ◽

Calcite Veins ◽

Tectonic Erosion ◽

Mass Flow Deposits ◽

Miocene Tectonics ◽

Mass Transport Deposits

Abstract The Súľov Conglomerates represent mass-transport deposits of the Súľov-Domaniža Basin. Their lithosomes are intercalated by claystones of late Thanetian (Zones P3 - P4), early Ypresian (Zones P5 - E2) and late Ypresian to early Lutetian (Zones E5 - E9) age. Claystone interbeds contain rich planktonic and agglutinated microfauna, implying deep-water environments of gravity-flow deposition. The basin was supplied by continental margin deposystems, and filled with submarine landslides, fault-scarp breccias, base-of-slope aprons, debris-flow lobes and distal fans of debrite and turbidite deposits. Synsedimentary tectonics of the Súľov-Domaniža Basin started in the late Thanetian - early Ypresian by normal faulting and disintegration of the orogenic wedge margin. Fault-related fissures were filled by carbonate bedrock breccias and banded crystalline calcite veins (onyxites). The subsidence accelerated during the Ypresian and early Lutetian by gravitational collapse and subcrustal tectonic erosion of the CWC plate. The basin subsided to lower bathyal up to abyssal depth along with downslope accumulation of mass-flow deposits. Tectonic inversion of the basin resulted from the Oligocene - early Miocene transpression (σ1 rotated from NW-SE to NNW-SSE), which changed to a transpressional regime during the Middle Miocene (σ1 rotated from NNE-SSW to NE-SW). Late Miocene tectonics were dominated by an extensional regime with σ3 axis in NNW-SSE orientation.

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A simple and efficient GIS tool for volume calculations of submarine landslides

Geo-Marine Letters ◽

10.1007/s00367-009-0176-0 ◽

2009 ◽

Vol 30 (5) ◽

pp. 541-547 ◽

Cited By ~ 10

Author(s):

David Julius Völker

Keyword(s):

Submarine Landslides ◽

Volume Calculations

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Effect of hydraulic and mechanical characteristics of sediment layers on water film formation in submarine landslides

Progress in Earth and Planetary Science ◽

10.1186/s40645-020-00375-7 ◽

2020 ◽

Vol 7 (1) ◽

Author(s):

Shogo Kawakita ◽

Daisuke Asahina ◽

Takato Takemura ◽

Hinako Hosono ◽

Keiji Kitajima

Keyword(s):

Tensile Strength ◽

Pore Pressure ◽

Mechanical Characteristics ◽

Film Formation ◽

Mass Movement ◽

Water Film ◽

Submarine Landslides ◽

Overburden Pressure ◽

Water Films ◽

Sediment Layers

Abstract Through two lab-scale experiments, we investigated the hydraulic and mechanical characteristics of sediment layers during water film formation, induced by elevated pore pressure—considered one of the triggers of submarine landslides. These involved (1) sandbox experiments to prove the effect of water films on mass movement in low slope gradients and (2) experiments to observe the effect of the tensile strength of semi-consolidated sediment layers on water film formation. Portland cement was used to mimic the degree of sediment cementation. We observed a clear relationship between the amount of cement and pore pressure during water film formation; pressure evolution and sediment deformation demonstrated the hydraulic and mechanical characteristics. Based on the results of these experiments, conditions of the sediment layers during water film formation are discussed in terms of pore pressure, permeability, tensile strength, overburden pressure, and tectonic stresses. The results indicate that the tensile strength of the sediment interface provides critical information on the lower limit of the water film formation depth, which is related to the scale of potential submarine landslides.

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Pre- and Post-Tsunami Depth Changes of Submarine Topography for the Analysis of Submarine Landslide-Induced Tsunami: Proposal of Digitization Method and Application to the Case of the 1923 Great Kanto Earthquake Tsunamis

10.1115/omae2021-63096 ◽

2021 ◽

Author(s):

Kazuki Murata ◽

Shinji Sassa ◽

Tomohiro Takagawa ◽

Toshikazu Ebisuzaki ◽

Shigenori Maruyama

Keyword(s):

Large Scale ◽

Interpolation Method ◽

Weighted Average ◽

Tokyo Bay ◽

Submarine Landslides ◽

Sagami Bay ◽

Seabed Topography ◽

Kanto Earthquake ◽

Before And After ◽

Tsunami Event

Abstract We first propose and examine a method for digitizing analog data of submarine topography by focusing on the seafloor survey records available in the literature to facilitate a detailed analysis of submarine landslides and landslide-induced tsunamis. Second, we apply this digitization method to the seafloor topographic changes recorded before and after the 1923 Great Kanto earthquake tsunami event and evaluate its effectiveness. Third, we discuss the coseismic large-scale seafloor deformation at the Sagami Bay and the mouth of the Tokyo Bay, Japan. The results confirmed that the latitude / longitude and water depth values recorded by the lead sounding measurement method can be approximately extracted from the sea depth coordinates by triangulation survey through the overlaying of the currently available GIS map data without geometric correction such as affine transformation. Further, this proposed method allows us to obtain mesh data of depth changes in the sea area by using the interpolation method based on the IDW (Inverse Distance Weighted) average method through its application to the case of the 1923 Great Kanto Earthquake. Finally, we analyzed and compared the submarine topography before and after the 1923 tsunami event and the current seabed topography. Consequently, we found that these large-scale depth changes correspond to the valley lines that flow down as the topography of the Sagami Bay and the Tokyo Bay mouth.

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What Is Tsunami Earthquake?

10.1115/omae2021-63104 ◽

2021 ◽

Author(s):

Toshikazu Ebisuzaki

Keyword(s):

Surface Waves ◽

Seismic Waves ◽

Submarine Landslides ◽

Lower Efficiency ◽

Tsunami Waves ◽

Tsunami Earthquakes ◽

Seismic Surface Waves ◽

Tsunami Earthquake ◽

Volcanic Islands ◽

2004 Tsunami

Abstract A tsunami earthquake is defined as an earthquake which induces abnormally strong tsunami waves compared with its seismic magnitude (Kanamori 1972; Kanamori and Anderson 1975; Tanioka and Seno 2001). We investigate the possibility that the surface waves (Rayleigh, Love, and tsunami waves) in tsunami earthquakes are amplified by secondly submarine landslides, induced by the liquefaction of the sea floor due to the strong vibrations of the earthquakes. As pointed by Kanamori (2004), tsunami earthquakes are significantly stronger in longer waves than 100 s and low in radiation efficiencies of seismic waves by one or two order of magnitudes. These natures are in favor of a significant contribution of landslides. The landslides can generate seismic waves with longer period with lower efficiency than the tectonic fault motions (Kanamori et al 1980; Eissler and Kanamori 1987; Hasegawa and Kanamori 1987). We further investigate the distribution of the tsunami earthquakes and found that most of their epicenters are located at the steep slopes in the landward side of the trenches or around volcanic islands, where the soft sediments layers from the landmass are nearly critical against slope failures. This distribution suggests that the secondly landslides may contribute to the tsunami earthquakes. In the present paper, we will investigate the rapture processes determined by the inversion analysis of seismic surface waves of tsunami earthquakes can be explained by massive landslides, simultaneously triggered by earthquakes in the tsunami earthquakes which took place near the trenches.

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