Liquefaction potential of coastal slopes induced by solitary waves

Young, Yin Lu; White, Joshua A.; Xiao, Heng; Borja, Ronaldo I.

doi:10.1007/s11440-009-0083-6

Cited by 45 publications

(20 citation statements)

References 48 publications

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“…If the tsunami waves broke before inundating, breaking‐wave‐generated turbulence, which is not accounted for here, could have affected the patterns of both turbulence generation and sediment suspension. Furthermore, pore pressure gradient‐induced sediment liquefaction, which can be important during drawdown [ Tonkin et al , 2003; Young et al , 2009], and infiltration of water into the soil onshore are not accounted for. There may also be other processes not yet identified that play an important role during tsunamis owing to the large flow velocities generated.…”

Section: Discussionmentioning

confidence: 99%

Process-based modeling of tsunami inundation and sediment transport

2011

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[1] The infrequent and unpredictable nature of tsunamis precludes the use of field experiments to measure the hydrodynamic and sediment transport processes that occur. Instead, these processes are often approximated from laboratory, numerical, and theoretical studies or inferred from observations of the resultant sediment deposits. Here Delft3D, a three-dimensional numerical model, is used to simulate the inundation and sediment transport of a tsunami similar in magnitude to the 26 December 2004 Indian Ocean tsunami over one measured and three idealized morphologies. The model is first shown to match well the observations taken at Kuala Meurisi, Sumatra, and then used to examine in detail the processes that occur during the tsunami. The model predicts that at a given cross-shore location the onshore flow accelerates rapidly to a maximum as the wavefront passes, and then gradually decelerates before reversing direction and flowing offshore. The onshore flow does not tend to zero everywhere at maximum inundation, but instead flow reversal occurs near the shoreline even as the wavefront continues to inundate landward. While some sediment is eroded by the passing wavefront, the suspension of sandy sediment is dominated by the long-duration, high-velocity backwash that occurs along the beach face and offshore of the shoreline. Some of the sediment suspended during backwash is advected shoreward by the subsequent wave, creating large spatial gradients in the suspended sediment concentrations, which may not be in equilibrium with the local hydrodynamics. The inundation and transport of sediment during a tsunami can be affected by complexities in the morphological profile and interactions between multiple waves, and many of the hydrodynamic and sediment transport processes predicted here are similar to analogous processes previously observed in the swash zone.Citation: Apotsos, A., G. Gelfenbaum, and B. Jaffe (2011), Process-based modeling of tsunami inundation and sediment transport,

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Section: Discussionmentioning

confidence: 99%

Process-based modeling of tsunami inundation and sediment transport

2011

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“…Interested reader should refer to (Young et al, 2009a) on this topic. In the present study, the wave loads on the bed are assumed to be small enough and the duration of the loading is short so that the soil behaves linear elastically and no failure model is necessary.…”

Section: Numerical Methods For the Wave-sediment Systemmentioning

confidence: 99%

“…Hence, the responses and failure of coastal slopes due to long wave runup and drawdown were not considered. Young et al (2009a) investigated the influence of solitary wave runup and drawdown on the soil responses using an uncoupled wave-soil model. The wave model was the same as the one presented here, but the sediment transport processes were not considered.…”

Section: Wave-induced Seabed Responsementioning

confidence: 99%

Hydro- and morpho-dynamic modeling of breaking solitary waves over a fine sand beach. Part II: Numerical simulation

2010

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“…It would thus be reasonable to characterize the constitutive response of the soil skeleton with a Mohr-Coulomb plasticity or similar models, since the compression cap is unlikely to be activated particularly when the effective-mean-normal stress decreases further as a result of the loss of suction with increased saturation. A simpler plasticity model such as the Mohr-Coulomb model also requires fewer material parameters than any of the more sophisticated constitutive models available in the literature (see [76]). For the soil at CB1, which is mostly colluvium, laboratory-determined values of friction angle are available [53,54].…”

Section: Introductionmentioning

confidence: 99%

Continuum deformation and stability analyses of a steep hillside slope under rainfall infiltration

2010

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Rainfall weakens an earth slope in a number of ways. It increases the degree of saturation of the soil, thereby breaking the bonds created by surface tension between the soil particles. When the volume of infiltrating water is large enough to mobilize fluid flow inside the soil matrix, the fluid exerts a downhill frictional drag on the slope, creating a destabilizing effect. When excess fluid can no longer infiltrate the slope due to increased saturation in the soil, it is discharged as a surface runoff and erodes the slope. In this paper, we present a physics-based framework for continuum modeling of a hydrologically driven slope failure similar to what occurred in a steep experimental catchment CB1 near Coos Bay, Oregon. We quantify the rainfall-induced slope deformation and assess the failure potential of the slope using finite element modeling that couples solid deformation with fluid pressure in an unsaturated soil. Results of the studies suggest that for a steep hillside slope underlain by a shallow bedrock similar to the CB1 site, failure would occur by multiple slide blocks with the failure surfaces emerging on the slope face. These results suggest that an infinite slope mechanism would be insufficient to represent the failure kinematics for a slope similar to CB1.

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Liquefaction potential of coastal slopes induced by solitary waves

Cited by 45 publications

References 48 publications

Process-based modeling of tsunami inundation and sediment transport

Process-based modeling of tsunami inundation and sediment transport

Hydro- and morpho-dynamic modeling of breaking solitary waves over a fine sand beach. Part II: Numerical simulation

Continuum deformation and stability analyses of a steep hillside slope under rainfall infiltration

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