Abstract
The use of the effective stress principle led to a general theory for the
strength and volumetric behavior of saturated soils. Presently, all constitutive models
for saturated soils are based on this principle. In 1959, Bishop proposed an equation
for the effective stress of unsaturated soils. However, it was severely criticized
because it could not explain by itself the phenomenon of collapse upon wetting.
Moreover, an analytical expression for the determination of its main parameter was
not provided, and in addition, its value could not be easily determined in the
laboratory. Since then, several equations to determine the value of parameter have
been proposed. Sixty years later, it is acknowledged that Bishop’s effective stress
equation can be employed to simulate the behavior of unsaturated soils when it is
complemented with a proper elastoplastic framework.
The Effective Stress Equation
Page: 10-21 (12)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010005
PDF Price: $30
Abstract
Based on the analysis of the equilibrium of solid particles of an unsaturated
sample subject to a certain suction, it is possible to establish an analytical expression
for Bishop´s parameter X. With this parameter, the effective stress can be evaluated
and used to predict the shear strength and volumetric behavior of unsaturated soils.
For the determination of parameter X, three elements are required: the saturated
fraction, the unsaturated fraction, and the degree of saturation of the unsaturated
fraction of the sample. The equation established for parameter X clarifies some
features of the strength of unsaturated soils that, up to now, had no apparent
explanation. A drawback to this expression is that the three required parameters for
the determination of X cannot be obtained from current experimental procedures.
The Porous-Solid Model
Page: 22-55 (34)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010006
PDF Price: $30
Abstract
Based on the analysis of the equilibrium of solid particles in a soil sample subject to a certain suction, an analytical expression for the value of Bishop´s parameter χ was established in the previous chapter. This parameter can be written as a function of the saturated fraction, the unsaturated fraction, and the degree of saturation of the unsaturated fraction of the soil. However, the determination of these three parameters cannot be made from current experimental procedures. Therefore, a porous-solid model simulating the structure of soils is proposed herein and used to determine these parameters. The data required to build up the porous-solid model are the void ratio of the sample and their grain and pore size distributions.
The Probabilistic Porous-Solid Model
Page: 56-82 (27)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010007
PDF Price: $30
Abstract
In the previous chapter, a computational network porous-solid model was
developed to simulate the hydraulic behavior of unsaturated soils. However, important
computational constraints make this model unpractical. In this chapter, a probabilistic
porous-solid model is developed to overcome these constraints. The probabilistic
model is an alternative to the use of computational network models and shows
important advantages. This model is built from the probability of a certain pore to be
filled or remain filled with water during a wetting or drying process, respectively. The
numerical results of the probabilistic model are compared with those of the
computational network model showing only slight differences. Then the model is
validated by making some numerical and experimental comparisons. Finally, a
parametric analysis is presented.
Applications of the Porous-Solid Model
Page: 83-103 (21)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010008
PDF Price: $30
Abstract
In the previous chapter, a probabilistic porous-solid model with the ability
to simulate both branches of the soil-water retention curve, was developed. In this
chapter, the model is used to interpret more realistically the results of mercury
intrusion porosimetry tests. Moreover, it is used to obtain the pore size distribution of
soils employing both branches of the soil-water retention curve as data. The numerical
and experimental comparisons for different soils show that the model approximately
reproduces the pore size distributions obtained from mercury intrusion porosimetry
tests. Finally, a procedure to fit the numerical with the experimental soil-water
retention curves in order to obtain the pore size distribution of soils is presented.
Compression Strength of Soils
Page: 104-111 (8)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010009
PDF Price: $30
Abstract
In this chapter, the probabilistic porous-solid model is used to determine
the mean effective stress of soils at failure. The plots of the deviator stress against the
mean effective stress show a unique failure line for a series of triaxial tests performed
at different confining net stress and suctions for both wetting and drying paths. This
result confirms that the proposed effective stress equation is adequate to predict the
shear strength of unsaturated soils. It also results in different strengths for wetting and
drying paths, as the experimental evidence indicates.
Tensile Strength
Page: 112-117 (6)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010010
PDF Price: $30
Abstract
In this chapter, the probabilistic porous-solid model is used to simulate the
tensile strength of unsaturated soils tested at different water contents. The strength of
unsaturated soils can be split into two parts: one related to the net stress and the other
to suction stress. The strength generated by suction has its origin in the additional
contact stresses induced to solid particles by water meniscus. This additional contact
stress is called matric suction stress when it is solely related to matric suction. In such
a case, the tensile strength of soils represents the matric suction stress of the material
at that particular water content. The numerical and experimental comparisons of the
tensile strength of unsaturated soils tested at different water contents show that the
probabilistic porous-solid model can simulate this phenomenon quite accurately.
Volumetric Behavior
Page: 118-146 (29)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010011
PDF Price: $30
Abstract
In this chapter, an equation to account for the volumetric behavior of unsaturated soils is proposed. This equation is based on the effective stress principle and results in a unifying framework for the volumetric behavior of both saturated and unsaturated soils. The numerical results of the proposed equation are compared with experimental results published by different researchers. These comparisons show that the equation is adequate to account for wetting-drying and net stress loadingunloading paths. This analysis confirms that the effective stress principle can be applied to the volumetric behavior of unsaturated soils.
Collapse Upon Wetting
Page: 147-170 (24)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010012
PDF Price: $30
Abstract
This chapter presents the modeling of the phenomenon of collapse upon
wetting using the effective stress approach established in Chapter 2 and the
elastoplastic framework for the volumetric behavior of soils proposed in the previous
chapter. Using the probabilistic porous-solid model, Bishop’s parameter can be
obtained to determine the current effective stress. The proposed framework includes
the hysteresis of the SWRC and, to some extent, the hydro-mechanical coupling of
unsaturated soils. This model is able to reproduce some particularities of the
phenomenon of collapse upon wetting that other models cannot simulate.
Expansive Soils
Page: 171-202 (32)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010013
PDF Price: $30
Abstract
In this chapter, the elastoplastic framework for the volumetric behavior of
soils developed in Chapters 8 and 9 is extended to account for the case of expansive
soils. The hydraulic behavior of the soil is simulated using the porous-solid model
developed in Chapter 4. The result is an elastoplastic framework where the value and
sign of the expansion index depend on the density of the soil as well as the state of
stresses and the direction of the increment of the effective stress with respect to the
yield surfaces in the plane of effective mean stress against suction. Experimental and
numerical comparisons show the ability of the model to simulate the behavior of
expansive soils under different stress paths.
Hydro-Mechanical Coupling
Page: 203-221 (19)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010014
PDF Price: $30
Abstract
The phenomenon of hysteresis during wetting-drying cycles can be
simulated using the porous-solid model developed in Chapter 3. This model employs
the current pore-size distribution of the material. The term “current pore-size
distribution” means that the size of pores can be updated as the soil deforms. In that
sense, the porous-solid model can be used advantageously for the development of
fully coupled hydro-mechanical constitutive models, as the influence of the
volumetric deformation on the retention curves and effective stresses can be easily
assessed. By including some experimental observations related to the behavior of the
pore size distribution of soils subjected to loading or suction increase, volume change
can be related to the reduction in the size of macropores. This methodology avoids
the necessity of any additional parameter or calibration procedure for the
hydromechanical coupling of unsaturated soils.
A Fully Coupled Critical State Model
Page: 222-253 (32)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010015
PDF Price: $30
Abstract
In previous chapters, it has been shown that the principle of effective
stresses can be applied to the shear strength, the tensile strength, and the volumetric
behavior of unsaturated soils. This chapter shows that the critical state line for
unsaturated soils shifts with respect to the saturated critical state line in a quantity that
depends on the suction stress. Taking into account this phenomenon and the influence
of hydro-mechanical coupling on the behavior of unsaturated soils, a fully coupled
general constitutive model for soils is developed. This model is based on the modified
Cam-Clay model but includes a yield surface with anisotropic hardening that takes
into account the shift of the critical state line with suction. The result is a very simple
model with symmetric stiffness matrix that can be used for the case of saturated,
unsaturated, and compacted materials.
Retention Curves in Deforming Soils
Page: 254-269 (16)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010016
PDF Price: $30
Abstract
During the determination of the main drying curve, the soil is subjected to
high suctions, which induce important volumetric deformations. These volumetric
deformations modify the pore size distribution of the sample affecting both the drying
and the wetting branch of the retention curves. Although most deformation occurs at
drying, this branch is only slightly affected by soil deformation. In contrast, the
wetting branch shows important shifting when volume change is considered. A
porous-solid model based on the grain and pore size distributions of the soil is coupled
with a mechanical model to simulate the soil-water retention curves while the material
is deforming.
Undrained Tests
Page: 270-283 (14)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010017
PDF Price: $30
Abstract
When undrained triaxial tests are performed, two main phenomena occur.
First, the compression of the sample produces an increase in the degree of saturation
and therefore, a reduction in the value of suction. Second, with the reduction in the
sizes of pores, the retention curves shift on the axis of suction. Thereafter, the
simulation of undrained triaxial tests requires the correct simulation of the
hydromechanical coupling phenomenon. A fully coupled constitutive model for
unsaturated soils is used herein to simulate the behavior of unsaturated soils subjected
to undrained conditions. The mechanical model is based on the modified Critical State
model and the effective stress concept. The hydraulic model uses the grain and pore
size distributions to approximately reproduce the structure of soils. This model is able
to simulate the soil-water retention curves during wetting-drying cycles. Plastic
volumetric strains modify the pore size distribution of the soil, which in turn affects
the retention curves and, therefore, the current effective stress. Some comparisons
between numerical and experimental results of undrained triaxial tests show the
adequacy of the model.
Compacted Soils
Page: 284-311 (28)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010018
PDF Price: $30
Abstract
When unsaturated soils are subjected to drained or undrained compression
tests, they approach the saturated compression line with different slopes. This
difference in slopes is produced by the amount of collapse of each path. During
compression, four main phenomena occur in these materials: first, with the reduction
in volume, the degree of saturation increases; second, with the reduction in the size of
pores, the soil-water retention curve shifts on the suction axis; third, these two
phenomena produce an increase in the suction stress and, finally, this increase in
suction stress produces a certain amount of collapse on the sample. In this chapter, a
coupled model is employed to simulate the volumetric behavior of compacted soils
under different stress paths. The comparison between experimental and numerical
results shows the pertinence of the model.
Hydraulic Conductivity
Page: 312-328 (17)
Author: Eduardo Rojas
DOI: 10.2174/9789815050356122010019
PDF Price: $30
Abstract
In this chapter, the probabilistic porous network model is employed to
establish a fully analytical equation for the relative hydraulic conductivity of soils.
From this approach, a parameter accounting for the proportion of pores of different
sizes forming continuous paths of saturated elements between the boundaries is used
to compute the hydraulic conductivity. This approach avoids the effect of the size of
the network on the results and the necessity of the pore-scale model approach required
by computational networks to obtain the hydraulic conductivity of soils. Similarly,
constraints related to computing time and memory size are avoided. In addition,
single, double, or triple structured soil can be considered for the network. The
theoretical and experimental comparisons indicate that capillary flow can account for
the hydraulic conductivity of soils for the full range of suction of sandy and silty soils.
Finally, all parameters required in the relative conductivity equation can be obtained
by fitting the numerical with the experimental retention curves.
Introduction
Towards A Unified Soil Mechanics Theory demonstrates mathematical models for saturated and unsaturated soils by defining the effective stress equation. Chapters present hydraulic models that simulate water distribution in pores. Parameters from these models are then used to demonstrate the use of an effective stress equation to understand the mechanics of soils that have different material constitutions. Key Features: -Sequentially explains soil modeling techniques for easy understanding -Demonstrates the use of an effective stress equation based on data from porous-solid models. -Explains how porous-solid models can simulate the soilwater retention curves of materials. -Establishes an elastoplastic framework for the volumetric behavior of unsaturated soils that is used to simulate the phenomenon of collapse upon wetting and the behavior of expansive soils. -Explains the practical application of fully a coupled hydro-mechanical (critical state) soil model -Includes scientific references for further reading The third edition includes additional information on retention curves in deforming curves, the application of a coupled hydro-mechanical model simulating undrained tests and the behavior of soils during static compaction, and the use of a porous-solid model to develop a fully analytical equation for the relative hydraulic conductivity of soils. The new chapters also cover the experimental parameters used to derive the models. This edition also updates material from previous editions, and adds new scientific references. Towards A Unified Soil Mechanics Theory paves the way for a universal theory of soil mechanics that has a wide range of applications. The book is a valuable reference to civil engineers, geotechnical engineers, earth scientists and hydrologists interested in soil mechanics at both academic and professional levels.