Simulation of liquefaction of unsaturated soil using critical state soil model

Komolvilas, Veerayut; Kikumoto, Mamoru

doi:10.1002/nag.2669

Cited by 14 publications

(11 citation statements)

References 25 publications

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“…From Equations 4 and 5, S r is given as a function of depth, S r ( z ). It is noted that the proposed method can incorporate several factors affecting the SWCC, such as air‐entry suction, 15 hydraulic hysteresis, 28 or the effect of density, 29 by replacing Equation 5 with an advanced SWCC model 11,30 …”

Section: Proposed Theory For Loosening Earth Pressure In Unsaturated mentioning

confidence: 99%

“…The effective stress proposed by Bishop 10 is usually used for unsaturated soils, as it can uniquely arrange the critical state stress ratio of unsaturated soils regardless of suction, s , as shown in Figure 2. By using this, σ z in Equation 2 is given as follows:

σ_{z}^{'} = σ_{z} - ({}, χ u_{w} + ((), 1 - χ) u_{a}),

where χ is the effective stress parameter for which S r is usually applied 11,31–33 . Borja 34 proved that χ is equal to S r based on the principles of thermodynamics.…”

Section: Proposed Theory For Loosening Earth Pressure In Unsaturated mentioning

confidence: 99%

“…The shear strength of unsaturated soils is usually evaluated using two independent stress state variables such as net normal stress and suction 7–9 . The effective stress tensor for unsaturated soils proposed by Bishop has also been applied widely to model the stress–strain behavior of unsaturated soils 10,11 . This tensor can uniquely describe the critical state stress ratio regardless of the degree of saturation 12 .…”

Section: Introductionmentioning

confidence: 99%

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A theory of loosening earth pressure above a shallow tunnel in unsaturated ground

Kikumoto

Cui

2020

Num Anal Meth Geomechanics

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A theory is proposed to evaluate the loosening earth pressure (vertical earth pressure after excavation) acting on a shallow tunnel in unsaturated ground with an arbitrary groundwater level. The theory is developed based on the limit equilibrium theory, combining soil-water characteristic curves, Mohr-Coulomb failure criteria, and effective stress for unsaturated soils. The proposed theory is applied to predict the vertical distribution of loosening earth pressure in unsaturated ground, which shows a significant difference from that in saturated ground. In unsaturated ground, suction contributes to the increase in effective loosening earth pressure and shear resistance. The remarkable effects of groundwater depth, soil type, and scale of overburden height and trapdoor width on loosening earth pressure are also revealed. Based on the soil-water characteristic curve, the degree of saturation decreases, which causes wet density to decrease and the total and effective loosening earth pressures to have contrary tendencies. Moreover, effective loosening earth pressures vary with soil type as the degree of saturation varies. The total loosening earth pressures are, however, very similar regardless of soil type, because wet density and shear resistance have similar tendencies. The proposed theory provides a valid model for loosening earth pressure in unsaturated ground that will be useful for shallow tunnel excavations. K E Y W O R D Slimit equilibrium theory, loosening earth pressure, modeling, shallow tunnel, unsaturated ground

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Section: Proposed Theory For Loosening Earth Pressure In Unsaturated mentioning

confidence: 99%

σ_{z}^{'} = σ_{z} - ({}, χ u_{w} + ((), 1 - χ) u_{a}),

where χ is the effective stress parameter for which S r is usually applied 11,31–33 . Borja 34 proved that χ is equal to S r based on the principles of thermodynamics.…”

Section: Proposed Theory For Loosening Earth Pressure In Unsaturated mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A theory of loosening earth pressure above a shallow tunnel in unsaturated ground

Kikumoto

Cui

2020

Num Anal Meth Geomechanics

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“…19 Models have been proposed that incorporate both hydraulic hysteresis and density effects in their SWCC models. [20][21][22][23][24][25] The SWCC models considering the effect of specific volume have been successfully implemented in the mathematical framework based on the principle of thermodynamics to study the fluid flow in unsaturated soils in the finite deformation range. 26,27 In the subloading surface model used by Kikumoto et al 21 and Komolvilas and Kikumoto, 22 volumetric movement of the normal consolidation line due to the variation in the degree of saturation was considered.…”

Section: Introductionmentioning

confidence: 99%

“…[20][21][22][23][24][25] The SWCC models considering the effect of specific volume have been successfully implemented in the mathematical framework based on the principle of thermodynamics to study the fluid flow in unsaturated soils in the finite deformation range. 26,27 In the subloading surface model used by Kikumoto et al 21 and Komolvilas and Kikumoto, 22 volumetric movement of the normal consolidation line due to the variation in the degree of saturation was considered. The wetting-induced collapse of unsaturated soils has been simulated [e.g., 19,21,28,29 ], but the effects of density and confining pressure, especially under anisotropic stress conditions, were not evaluated.…”

Section: Introductionmentioning

confidence: 99%

Mechanism of wetting–induced deformation and failure of unsaturated soils

Komolvilas

Kikumoto

Kyokawa

2022

Num Anal Meth Geomechanics

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The mechanisms of hydraulic collapse (wetting‐induced deformation) are studied through a series of simulations using a model for unsaturated soils. The model is a critical state soil model extended for unsaturated soils using Bishop's effective stress tensor, the state boundary surface (SBS) moving with the change in the degree of saturation, and a rational soil‐water characteristic curve that takes account of density and hydraulic hysteresis. Comparisons with published experimental data validate the proposed model. The simulation results show that the model adequately captures the hydraulic collapse behavior under both isotropic and anisotropic stress conditions. The effects of density, mean net stress, and deviatoric stress on the hydraulic collapse behavior are further investigated through a parametric calculation, and the mechanics of the wetting–induced instability are discussed. The effects of suction history, namely repeated wetting and drying cycles, on the deformation and failure, are also presented. The proposed model provides a validated method for modeling hydromechanical collapse in unsaturated soil and provides a better understanding of the mechanisms involved.

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Heat transport from atmosphere through the subsurface to drinking‐water supply pipes

Nissler,

Scherrer,

Class

et al. 2023

Vadose Zone Journal

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Drinking‐water quality in supply pipe networks can be negatively affected by high temperatures during hot summer months due to detrimental bacteria encountering ideal conditions for growth. Thus, water suppliers are interested in estimating the temperature in their distribution networks. We investigate both experimentally and by numerical simulation the heat and water transport from ground surface into the subsurface, (i.e., above drinking‐water pipes). We consider the meteorological forcing functions by a sophisticated approach to model the boundary conditions for the heat balance at the soil–atmosphere interface. From August to December 2020, soil temperatures and soil moisture were measured dependent on soil type, land‐use cover, and weather data at a pilot site, constructed specifically for this purpose at the University of Stuttgart with polyethylene and cast‐iron pipes installed under typical in situ conditions. We included this interface condition at the atmosphere–subsurface boundary into an integrated non‐isothermal, variably saturated (Richards') the numerical simulator DuMux 3. This allowed, after calibration, to match measured soil temperatures with ±2°C accuracy. The land‐use cover influenced the soil temperature in 1.5 m more than the soil material used for back‐filling the trench above the pipe.

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Simulation of liquefaction of unsaturated soil using critical state soil model

Cited by 14 publications

References 25 publications

A theory of loosening earth pressure above a shallow tunnel in unsaturated ground

A theory of loosening earth pressure above a shallow tunnel in unsaturated ground

Mechanism of wetting–induced deformation and failure of unsaturated soils

Heat transport from atmosphere through the subsurface to drinking‐water supply pipes

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