CONTENTS
CHAPTER 1
·
1.1
INTRODUCTION
·
1.2
DEFINITION
·
1.3
WHAT IS LIQUEFACTION & WHY DOES IT OCCUR ?
·
1.4
CAUSE BEHIND LIQUEFACTION
CHAPTER 2
·
LITERATURE REVIEW
CHAPTER 3
·
3.1 SOIL PROPERTIES DURING LIQUEFACTION
·
3.2 POREWATER PRESSURE
DURING LIQUEFACTION
·
3.3
EARTHQUAKE LIQUEFACTION
·
3.4
FACTORS AFFECTING SOIL LIQUEFACTION
·
3.5
CONSEQUENCE OF LIQUEFACTION
CHAPTER 4
·
4.1
SAND PHENOMENONS
CHAPTER 5
·
5.1 SOIL LIQUEFACTION TRAGEDIES
·
5.2
EFFECTS
·
5.3
MITIGATION METHODS
CHAPTER 6
·
6.1
SUMMARY
REFERENCES
REFERENCES
ABSTRACT
The presence of silt and clay particles has long been thought to affect the behavior of a sand under cyclic loading. Unfortunately, a review of studies published in the literature reveals that no clear conclusions can be drawn as to how altering fines content and plasticity actually affects the liquefaction resistance of a sand. In fact, the literature contains what appears to be contradictory evidence. There is a need to clarify the effects of fines content and plasticity on the liquefaction resistance of sandy soils, and to determine methods for accounting for these effects in engineering practice.
In order to help answer these questions, a program of research in the form of a laboratory parametric study intended to clarify the effects which varying fines content and plasticity have upon the liquefaction resistance of sandy sands was undertaken. The program of research consisted of a large number of cyclic triaxial tests performed on two sands with varying quantities of plastic and non-plastic fines. The program of research also examined the applicability of plasticity based liquefaction criteria and the effects of fines content and plasticity on pore pressure generation. Lastly, a review of how the findings of this study may affect the manner in which simplified analyses are performed in engineering practice was made. The results of the study performed are used to clarify the effects of non-plastic fines content and resolve the majority of the inconsistencies in the literature. The effects of plastic fines content and fines plasticity are shown to be different than has been previously reported. The validity of plasticity based liquefaction criteria is established, the mechanism responsible for their validity is explained, and a new simplified criteria proposed. The effects of fines content and plasticity on pore pressure generation are discussed, and several recommendations are made for implementing the findings of this study into engineering practice.
CHAPTER
1
1.1
INTRODUCTION
Liquefaction
is the phenomena when there is loss of strength in saturated and cohesion-less
soils because of increased pore water pressures and hence reduced effective
stresses due to dynamic loading. It is a phenomenon in which the strength and
stiffness of a soil is reduced by earthquake shaking or other rapid loading.
Liquefaction
occurs in saturated, saturated soils are the soils in which the space between
individual particles is completely filled with water. This water exerts a
pressure on the soil particles that. The water pressure is however relatively
low before the occurrence of earthquake. But earthquake shaking can cause the
water pressure to increase to the point at which the soil particles can readily
move with respect to one another.
Although
earthquakes often triggers this increase in water pressure, but activities such
as blasting can also cause an increase in water pressure. When liquefaction
occurs, the strength of the soil decreases and the ability of a soil deposit to
support the construction above it.
Soil
liquefaction can also exert higher pressure on retaining walls, which can cause
them to slide or tilt. This movement can cause destruction of structures on the
ground surface and settlement of the retained soil.
It
is required to recognize the conditions that exist in a soil deposit before an
earthquake in order to identify liquefaction. Soil is basically an assemblage
of many soil particles which stay in contact with many neighboring soil. The
contact forces produced by the weight of the overlying particles holds
individual soil particle in its place and provide strength.
1.2
DEFINITION
“A Phenomenon where by
a saturated or partially saturated soil substantially loses strength and
stiffness in response to an applied stress, usually earthquake Shaking or other
sudden change in stress condition, causing it to behave like a liquid” is called Soil Liquefaction.
1.3
WHAT IS LIQUEFACTION & WHY DOES IT OCCUR ?
Liquefaction
is the process that leads to a soil suddenly losing strength, most commonly as
a result of ground shaking during a large earthquake. Not all soils however,
will liquefy in an earthquake.
The
following are particular features of soils that potentially can liquefy:
·
They are sands and
silts and quite loose in the ground. Such soils do not stick together the way
clay soils do.
·
They are below the
watertable, so all the space between the grains of sand and silt are filled
with water. Dry soils above the watertable won’t liquefy.
When
an earthquake occurs the shaking is so rapid and violent that the sand and silt
grains try to compress the spaces filled with water, but the water pushes back
and pressure builds up until the grains ‘float’ in the water. Once that happens
the soil loses its strength – it has liquefied. Soil that was once solid now
behaves like a fluid.
Fig (1.30 &
1.31) Some examples of Soil Liquefaction.
WHAT
HAPPENS NEXT ?
Liquefied
soil, like water, cannot support the weight of whatever is lying above it – be
it the surface layers of dry soil or the concrete floors of buildings.
The
liquefied soil under that weight is forced into any cracks and crevasses it can
find, including those in the dry soil above, or the cracks between concrete
slabs. It flows out onto the surface as boils, sand volcanoes and rivers of
silt. In some cases the liquefied soil flowing up a crack can erode and widen
the crack to a size big enough to accommodate a car.
Some
other consequences of the soil liquefying are:
·
Settlement of the
ground surface due to the loss of soil from underground.
·
Loss of support to
building foundations.
·
Floating of manholes,
buried tanks and pipes in the liquefied soil - but only if the tanks and pipes
are mostly empty.
·
Near streams and
rivers, the dry surface soil layers can slide sideways on the liquefied soil
towards the streams. This is called lateral spreading and can severely damage a
building.
It
typically results in long tears and rips in the ground surface that look like a
classic fault line.
Not
all of a building’s foundations might be affected by liquefaction.
The
affected part may subside (settle) or be pulled sideways by lateral spreading,
which can severely damage the building. Buried services such as sewer pipes can
be damaged as they are warped by lateral spreading, ground settlement or
flotation.
Fig (1.32 &
1.33) Some examples of Soil Liquefaction.
AFTER
THE EARTHQUAKE
After
the earthquake shaking has ceased, and liquefaction effects have diminished
(which may take several hours).
The
permanent effects include:
•
Lowering of ground levels where liquefaction and soil ejection has occurred. Ground
lowering may be sufficient to make the surface close to or below the watertable,
creating ponds.
•
Disruption of ground due to lateral spreading.
The
liquefied soil that is not ejected onto the ground surface re-densifies and
regains strength, in some cases re-densified soil is stronger than before the
earthquake.
Careful
engineering evaluation is required to determine whether ground that has
suffered liquefaction can be redeveloped.
Fig (1.34 & 1.35) some examples of Soil Liquefaction.
1.4
CAUSE BEHIND LIQUEFACTION
It
is required to recognize the conditions that exist in a soil deposit before an
earthquake in order to identify liquefaction. Soil is basically an assemblage
of many soil particles which stay in contact with many neighboring soil. The contact
forces produced by the weight of the overlying particles holds individual soil
particle in its place and provide strength.
·
Soil grains in a soil
deposit. The height of the blue column to the right represents the level of
pore-water pressure in the soil.
·
The length of the arrows
represents the size of the contact forces between individual soil grains. The
contact forces are large when the pore-water pressure is low.
|
Occurrence
of liquefaction is the result of rapid load application and break down of the
loose and saturated sand and the loosely-packed individual soil particles tries
to move into a denser configuration. However, there is not enough time for the
pore-water of the soil to be squeezed out in case of earthquake. Instead, the water
is trapped and prevents the soil particles from moving closer together. Thus,
there is an increase in water pressure which reduces the contact forces between
the individual soil particles causing softening and weakening of soil deposit.
In extreme conditions, the soil particles may lose contact with each other due
to the increased pore-water pressure. In such cases, the soil will have very
little strength, and will behave more like a liquid than a solid - hence, the
name "liquefaction".
Fig (1.40) Nishinomia Bridge 1995 Kobe earthquake, Japan.
CHAPTER 2
LITERATURE
REVIEW
Carmine
Paul Polito (10 Dec 1999)
The published results of geotechnical studies were examined in order to determine the state of knowledge on the effects of fines content and plasticity on the liquefaction resistance and pore pressure generation characteristics of sandy soils.
2.1 The Effects of Fine Content and Plasticity on
Liquefaction Resistance
Both clean sands and sands containing fines have been shown to be liquefiable in the field (Mogami and Kubo (1953); Robertson and Campenella (1985); and Holzer et al. (1989)) and in the laboratory (Lee and Seed (1967a); Chang et al. (1982); and Koester (1994)). Additionally, non-plastic silts, most notably mine tailings, have also been found to be susceptible to liquefaction (Dobry and Alvarez (1967); Okusa et al. (1980); and Garga and McKay (1984)). A review of the literature, however, shows conflicting evidence as to the effect which fines have on the liquefaction resistance or cyclic strength of a sand. The main factors that are reviewed here are the effects of non-plastic fines content and the effects of plastic fines content and plasticity on the liquefaction resistance of sandy soils.
2.2 The Effects
Of Non-Plastic Fine Content
There is no clear consensus in the literature as to the effect which increasing non-plastic fines content has upon the liquefaction resistance of a sand. Both field and laboratory studies have been performed, and the results of these studies indicate that increasing the non-plastic fines content in a sand will either increase the liquefaction resistance of the sand, decrease the liquefaction resistance of the sand, or decreases the liquefaction resistance until some limiting fines content is reached, and then increases its resistance. To further complicate issues, some researchers have shown that the liquefaction resistance of silty sands is not a function of the silt content of the soil so much as it is a function of the soil’s sand skeleton void ratio.
2.3
The Effects of Plastic Fines Content and
Plasticity And Plasticity Based
Liquefaction Criteria
There is general agreement in the literature as to the effect which the quantity and plasticity of the fine-grained material has on the liquefaction resistance of a sandy soil. There is agreement that whether the fine grained material is silt or clay, or more importantly, whether it behaves plastically or non-plastically, tends to make an important, consistent difference in the cyclic strength of the soil. The majority of studies have shown that the presence of plastic fines tend to increase the liquefaction resistance of a soil.
2.4 Plasticity
Based Liquefaction Criteria
Jennings (1980) presents a listing of the “thresholds to liquefaction” used by engineers in the People’s Republic of China to separate soils which are considered liquefiable from those considered non-liquefiable. Soils meeting these criteria are considered to be nonliquefiable and include those with plasticity indexes greater than 10, clay contents greater than 10 percent, relative densities greater than 75 percent, and void ratios less than 0.80.
Other criteria presented are related to epicentral distance, intensity, grain size and gradation, the depth of the sand layer, and the depth of the water table.
Seed et al. (1973) in their review of the slides that occurred in the Lower San Fernando Dam during the February 1971 San Fernando earthquake presented a modified form of the Chinese criteria. As reported by Marcuson et al. (1990), soils with greater than 15 percent material finer than 0.005 mm, liquid limits greater than 35 percent, and water contents less than 90 percent of the liquid limit should be safe from liquefaction.
2.5 The Effects Of Fines Content And Plasticity On
Pore Pressure Generation
The
rate and magnitude of pore pressure generation may have important effects on
the shear
strength, stability, and settlement characteristics of a soil mass, even if the
soil does not
liquefy. Similarly, the peak pore pressure generated may affect the stability
of structure
founded on, or in the soil mass.
2.6
Rate And Magnitude Of Pore Pressure
Generation
There are two methods of examining the rate and magnitude of pore pressure generation during cyclic loading which have been reported in the literature. The first is to examine the pore pressures generated in relation to the ratio of the number of cycles of loading applied to the number of cycles required to cause liquefaction. This is the method used by Lee and Albaisa (1974). Pore pressures may also be measured in terms of the strain required to generate them. This is the approached taken by Dobry et al (1982).
CHAPTER
3
3.1 SOIL PROPERTIES DURING LIQUEFACTION
·
SHRINKAGE LIMIT
The shrinkage
limit (SL) is the water content where further loss of moisture will not result
in any more volume reduction.
·
PLASTIC LIMIT
The plastic
limit (PL) is determined by rolling out a thread of the fine portion of a soil
on a flat, non-porous surface.
·
LIQUID LIMIT
The liquid
limit (LL) is often conceptually defined as the water content at which the
behavior of a clayey soil changes from plastic to liquid . Actually,
clayey soil does have a very small shear strength at the liquid limit and the
strength decreases as water content increases; the transition from plastic to
liquid behavior occurs over a range of water contents.
·
THE ATTERBERG LIMITS
The Atterberg Limits are a basic
measure of the critical water contents of a fine-grained soil, such as its
shrinkage limit, plastic limit, and liquid limit. As a dry, clayey soil takes
on increasing amounts of water, it undergoes dramatic and distinct changes in
behavior and consistency. Depending on the water
content of the soil, it may appear in four states: solid, semi-solid,
plastic and liquid. In each state, the consistency and behavior of a soil is
different and consequently so are its engineering properties. Thus, the
boundary between each state can be defined based on a change in the soil's
behavior. The Atterberg limits can be used to distinguish between silt and clay, and it can
distinguish between different types of silts and clays. These limits were
created by Albert Atterberg, a Swedish chemist. They were
later refined by Arthur Casagrande. These distinctions
in soil are used in assessing the soils that are to have structures built on.
Soils when wet retain water and some expand in volume. The amount of expansion
is related to the ability of the soil to take in water and its structural
make-up (the type of atoms present). These tests are mainly used on clayey or
silty soils since these are the soils that expand and shrink due to moisture
content. Clays and silts react with the water and thus change sizes and have
varying shear strengths. Thus these tests are used widely in the preliminary
stages of designing any structure to ensure that the soil will have the
correct amount of shear strength and not too much
change in volume as it expands and shrinks with different moisture contents.
As a hard, rigid solid
in the dry state, soil becomes a crumbly (friable) semisolid when a certain
moisture content, termed the shrinkage limit, is reached. If it is an expansive
soil, this soil will also begin to swell in volume as this moisture content is
exceeded. Increasing the water content beyond the soil's plastic limit will
transform it into a malleable, plastic mass, which causes additional swelling.
The soil will remain in this plastic state until its liquid limit is exceeded,
which causes it to transform into a viscous liquid that flows when jarred.
3.2 POREWATER PRESSURE
DURING LIQUEFACTION
A
state of 'soil liquefaction' occurs when the effective stress of
soil is reduced to essentially zero, which corresponds to a complete loss
of shear
strength. This may be initiated by either monotonic
loading (e.g. single sudden occurrence of a change in stress – examples include
an increase in load on an embankment or sudden loss of toe support) or cyclic
loading (e.g. repeated change in stress condition – examples include wave loading or earthquake shaking)
.
In both cases a soil in a saturated loose state, and one which may generate
significant pore water pressure on a change in load are the most likely to
liquefy.
This is because a loose soil has the tendency
to compress when sheared, generating large excess Porewater
Pressure as load is transferred from the soil
skeleton to adjacent pore water during undrained loading. As pore water
pressure rises a progressive loss of strength of the soil occurs as effective
stress is reduced. It is more likely to occur
in sandy or non-plastic silty soils, but may in rare cases occur in gravels and
clays.
OCCURRENCE
OF SOIL LIQUEFACTION
·
Liquefaction is more likely
to occur in loose to moderately saturated granular soils with poor drainage,
such as silty sands or sands and gravels capped
or containing seams of impermeable sediments.
·
During wave loading,
usually cyclic undrained loading, e.g. seismic loading,
loose sands tend to decrease in volume, which produces an
increase in their pore
water pressures and consequently a
decrease in shear
strength, i.e. reduction in effective
stress
·
The resistance of the
cohesionless soil to liquefaction will depend on the density of the soil,
confining stresses, soil structure. The magnitude and duration of the cyclic
loading, and the extent to which shear stress reversal occurs.
·
Depending on the
initial void ratio,
the soil material can respond to loading either strain-softening or strain-hardening. Strain-softened soils, e.g. loose sands, can
be triggered to collapse, either monotonically or cyclically, if the static
shear stress is greater than the ultimate or steady-state shear strength of the
soil. In this case flow
liquefaction occurs.
3.3
EARTHQUAKE LIQUEFACTION
Fig (3.30) Sand boils that erupted during the 2011 Christchurch earthquake.
The
pressures generated during large earthquakes with many cycles of shaking can
cause the liquefied sand and excess water to force its way to the ground
surface from several metres below the ground. This is often observed as "sand boils"
also called "sand blows" or "sand volcanoes"
(as they appear to form small volcanic craters) at the ground surface. The
phenomenon may incorporate both flow of already liquefied sand from a layer
below ground, and a quicksand effect
whereby upward flow of water initiates liquefaction in overlying non-liquefied
sandy deposits due to buoyancy.
One
positive aspect of soil liquefaction is the tendency for the effects of
earthquake shaking to be significantly damped (reduced)
for the remainder of the earthquake. This is because liquids do not support a shear stress and
so once the soil liquefies due to shaking, subsequent earthquake shaking
(transferred through ground by shear waves)
is not transferred to buildings at the ground surface.
Studies
of liquefaction features left by prehistoric earthquakes, called Paleoliquefaction or Paleoseismology,
can reveal a great deal of information about earthquakes that occurred before
records were kept or accurate measurements could be taken. Soil liquefaction
induced by earthquake shaking is also a major contributor to urban
seismic risk.
TECHNICAL
DEFINITION
A
state of Soil Liquefaction occurs
when the effective stress of
soil is reduced to essentially zero, which corresponds to a complete loss
of shear
strength. This may be initiated by either monotonic
loading or cyclic loading .
TYPES
OF FAILURES
1.
Cyclic Mobility
2.
Over Turning
3.
Sand Boiling
These
are some of failures.
3.4
FACTORS AFFECTING SOIL LIQUEFACTION
1. Soil Type
2.
Grain size and its distribution
3.
Initial relative density
4.
Vibration characterstics
5.
Location of drainage and dimension of
deposit
6. Surcharge
load
7.
Method of soil formation
8.
Period under sustained load
9.
Previous strain history
10.
Trapped Air
These
are some factors affecting Soil Liquefaction.
3.5
CONSEQUENCE OF LIQUEFACTION
ü
Settlements
ü
Lateral spreads
ü
Lateral flows
ü
Loss of lateral support
ü
Loss of bearing support
ü
Flotation of bearing
supports
These
are some consequences of Soil Liquefaction.
CHAPTER 4
4.1
SAND PHENOMENONS
·
QUICK
SAND
QuickSand forms when water
saturates an area of loose sand and the ordinary sand is agitated. When the
water trapped in the batch of sand cannot escape, it creates liquefied soil
that can no longer support weight. Quicksand can be formed by standing or
(upwards) flowing underground water (as from an underground spring), or by
earthquakes. In the case of flowing underground water, the force of the water
flow opposes the force of gravity, causing the granules of sand to be more
buoyant. In the case of earthquakes, the shaking force can increase the
pressure of shallow groundwater, liquefying sand and silt deposits. In both
cases, the liquefied surface loses strength, causing buildings or other objects
on that surface to sink or fall over.
The saturated sediment
may appear quite solid until a change in pressure or shock initiates the
liquefaction, causing the sand to form a suspension with each grain surrounded
by a thin film of water. This cushioning gives quicksand, and other liquefied
sediments, a spongy, fluidlike texture. Objects in the liquefied sand sink to
the level at which the weight of the object is equal to the weight of the
displaced sand/water mix and the object floats due to
its buoyancy.
Fig (4.10 & 4.11) Some examples for QuickSand
Phenomenon.
·
QUICK
CLAY
Quick clay,
also known as Leda Clay in Canada,
is a water-saturated gel, which in its solid form
resemble a unique form of highly sensitive clay. This clay has a
tendency to change from a relatively stiff condition to a liquid mass when it
is disturbed. This gradual change in appearance from solid to liquid is a
process known as spontaneous liquefaction. The clay retains a solid structure
despite the high water content (up to 80 volume-%), because surface
tension holds water-coated flakes of clay
together in a delicate structure. When the structure is broken by a shock or
sufficient shear, it turns to a fluid state.Quick clay is only found in the
northern countries such as Russia, Canada, Alaska in
the U.S., Norway, Sweden,
and Finland,
which were glaciated during the Pleistocene epoch.
Quick
clay has been the underlying cause of many deadly landslides.
In Canada alone, it has been associated with more than 250 mapped landslides.
Fig (4.12 & 4.13)
Some examples for Quick Clay Phenomenon.
CHAPTER 5
5.1 SOIL LIQUEFACTION TRAGEDIES
Fig (5.10) 1964
Niigata earthquake.
Fig (5.11) 1964
Alaska earthquake.
Fig (5.12) 1989
Loma Prieta earthquake.
Fig (5.13)
2010
Canterbury earthquake.
Fig (5.14) Liquefied soil exerts higher
pressure on retaining walls,which can cause them to tilt or slide.
Fig (5.15) Foundation failure in Kerala
during Tsunami (December 26th, 2004)
5.2
EFFECTS
The effects of lateral spreading (River Road in 2011 Christchurch earthquake)
Damage in Brooklands from the 2010 Canterbury earthquake, where buoyancy caused by soil liquefaction pushed up an underground service including this manhole
The
effects of soil liquefaction on the built environment can be extremely damaging.
Buildings whose foundations bear directly on sand which liquefies will
experience a sudden loss of support, which will result in drastic and irregular
settlement of the building causing structural damage, including cracking of
foundations and damage to the building structure itself, or may leave the
structure unserviceable afterwards, even without structural damage. Where a
thin crust of non-liquefied soil exists between building foundation and
liquefied soil, a 'punching shear' type foundation failure may occur. The
irregular settlement of ground may also break underground utility lines. The
upward pressure applied by the movement of liquefied soil through the crust
layer can crack weak foundation slabs and enter buildings through service
ducts, and may allow water to damage the building contents and electrical
services.
Bridges
and large buildings constructed on pile foundations may
lose support from the adjacent soil and buckle,
or come to rest at a tilt after shaking.
Sloping
ground and ground next to rivers and lakes may slide on a liquefied soil layer
(termed 'lateral spreading'), opening
large cracks or fissures in the ground, and can cause significant damage to
buildings, bridges, roads and services such as water, natural gas, sewerage,
power and telecommunications installed in the affected ground. Buried tanks and
manholes may float in the liquefied soil due to buoyancy. Earth
embankments such as flood levees and earth dams may
lose stability or collapse if the material comprising the embankment or its
foundation liquefies.
5.3
MITIGATION METHODS
Methods to mitigate
the effects of soil liquefaction have been devised by earthquake engineers and include
various soil compaction techniques such as :
·
Vibro Compaction (Compaction of the soil by depth
vibrators)
These methods result
in the densification of soil and enable buildings to withstand soil
liquefaction.
Existing buildings can
be mitigated by injecting grout into the soil to stabilize the layer of soil
that is subject to liquefaction.
1.
Vibro
Compaction.
2.
Dynamic
Compaction.
These are some methods
to mitigate the effects of Soil Liquefaction.
CHAPTER
6
6.1
SUMMARY
This
Promotes simple criterion based on “key” soil parameters that help partition
liquefiable and non-liquefiable silty soils. A brief review of the physical characteristics
of silts and clays is
first
given to help clarify some misconceptions about silty soils. Clay content and
liquid limit are
then
considered as two “key” soil parameters that help partition liquefiable and
non-liquefiable
silty
soils. Several case histories are presented that illustrate the applicability
of using clay content as a “key” soil parameter. Attention is drawn to an
analogy between the liquid limit and the shear strength of a soil.
This
analogy is expanded to show that the liquid limit can be regarded as a “key”
soil parameter that gives a relative measure of liquefaction susceptibility.
Inadequacies of basing criteria for liquefaction of silty soils on just one
“key” parameter are finally discussed, leading to the promotion of simple
criteria for liquefaction of silty soils, utilising together both the clay
content and the liquid limit soil parameters.
REFERENCES
1. Kenji
Ishihara, Norio Oyagi, Text Book of Soil And Foundations, Vol 30, No 4, 73-89,
Dec 1990.
2.
Carmine Paul Polito, ‘The Effects Of Non-Plastic and Plastic Fines
On The Liquefaction Of Sandy Soils’, 10 December 1999.
3. Hans
F.Winterkorn and Hsai-Yang Fang., ‘Foundation Engineering Handbook’.
4.
T.G.Sitharam,
L.GovindaRaju and A. Sridharan (2004).,‘Dynamic properties and liquefaction
potential of soils’, Special Section: Geotechnics and Earthquake Hazards,
Current Science, Vol.87,No.10,25 November 2004.
5.
Alisha Kaplan
(2004).,‘Soil Liquefaction’ Undergraduate Research, Mid-America Earthquake
Center and Georgia Institute of Technology, May 2004.
6.
EN1998-5:2004
Eurocode 8 – Design of structures for earthquake resistance. Part 5:
Foundations, retaining structures and geotechnical aspects.
Brussels: European Committee for Standardisation. 2004.
7.
http://en.wikipedia.org/wiki/soil_liquefaction
8.
http://geology.com>Home>Geological Hazards
9.
http://a4academics.com>Home>Seminar Topics>Liquefaction
10. http://slideshare.net/jagadanand/liquefaction_of_soil
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