Based on part of the GeotechniCAL reference package by Prof. John Atkinson

Stress in the ground

When a load is applied to soil, it is carried by the water in the pores as well as the solid grains. The increase in pressure within the porewater causes drainage (flow out of the soil), and the load is transferred to the solid grains. The rate of drainage depends on the permeabilityof the soil. The strength and compressibility of the soil depend on the stresses within the solid granular fabric. These are called effective stresses.

 

 


Total stress

Top
The total vertical stress acting at a point below the ground surface is due to the weight of everythinglying above: soil, water, and surface loading. Total stresses are calculated from the unit weight of the soil.

Unit weight ranges are:
dry soil  gd 14 - 20 kN/m³ (average 17kN/m³)
saturated soil  gg 18 - 23 kN/m³  (average 20kN/m³)
water  g 9.81 kN/m³   (» 10 kN/m³)

See Description and classification

Any change in vertical total stress (sv) may also result in a change in the horizontal total stress (sh) at the same point. The relationships between vertical and horizontal stress are complex.

 


Total stress in homogeneous soil

total stress
Total stress increases with depth and with unit weight: Vertical total stress at depth z,
sv = g.z
Simple total stress calculator 
g z sv
The symbol for total stress may also be written sz,
i.e. related to depth z.
The unit weight, g, will vary with the water content of the soil.
gd  £  g  £  gg

Total stress below a river or lake

total stress
The total stress is the sum of the weight of the soil up to the surface and the weight of water above this: Vertical total stress at depth z,
sv = g .z + gw .zw
where
g = unit weight of the saturated soil,

i.e. the total weight of soil grains and water
gw = unit weight of water
The vertical total stress will change with changes in water level and with excavation. Note that free water (i.e. water outside the soil) applies a total stress to a soil surface.
Simple total stress calculator
g z zw sv  


Total stress in multi-layered soil

total stress
The total stress at depth z is the sum of the weights of soil in each layer thickness above.
Vertical total stress at depth z,
sv = g1d1 + g2d2 + g3(z - d1 - d2)
where
g1, g2, g3, etc. = unit weights of soil layers 1, 2 , 3, etc. respectively
If a new layer is placed on the surface the total stresses at all points below will increase.
 Layer 1 2 3
Thickness
Unit weight
stress @m = kPa
Enter a value in any box (except the last) then click outside the box to see the effect

Total stress in unsaturated soil

total stress

Just above the water table the soil will remain saturated due to capillarity, but at some distance above the water table the soil will become unsaturated, with a consequent reduction in unit weight (unsaturated unit weight = gu)

sv = gw . zw + gg(z - zw)


The height above the water table up to which the soil will remain saturated depends on the grain size.
See Negative pore pressure (suction).
 


Total stress with a surface surcharge load

total stress
The addition of a surface surcharge load will increase the total stresses below it. If the surcharge loading is extensively wide, the increase in vertical total stress below it may be considered constant with depth and equal to the magnitude of the surcharge.

Vertical total stress at depth z,
sv = g .z + q
For narrow surcharges, e.g. under strip and pad foundations, the induced vertical total stresses will decrease both with depth and horizontal distance from the load. In such cases, it is necessary to use a suitable stress distribution theory - an example is Boussinesq's theory.


Pore pressure

Top
The water in the pores of a soil is called porewater. The pressure within this porewater is called pore pressure (u). The magnitude of pore pressure depends on:
 


Groundwater and hydrostatic pressure

Pore pressure

Under hydrostatic conditions (no water flow) the pore pressure at a given point is given by the hydrostatic pressure:

u = gw .hw
where
hw = depth below water table or overlying water surface
It is convenient to think of pore pressure represented by the column of water in an imaginary standpipe; the pressure just outside being equal to that inside.
 
 


Water table, phreatic surface

Pore pressure
The natural static level of water in the ground is called the water table or the phreatic surface (or sometimes the groundwater level). Under conditions of no seepage flow, the water table will be horizontal, as in the surface of a lake. The magnitude of the pore pressure at the water table is zero. Below the water table, pore pressures are positive.
u = gw .hw
In conditions of steady-state or variable seepage flow, the calculation of pore pressures becomes more complex.
See Groundwater

 


Negative pore pressure (suction)

Pore pressure
Below the water table, pore pressures are positive. In dry soil, the pore pressure is zero. Above the water table, when the soil is saturated, pore pressure will be negative.
u = - gw .hw

The height above the water table to which the soil is saturated is called the capillary rise, and this depends on the grain size and type (and thus the size of pores):
· in coarse soils capillary rise is very small
· in silts it may be up to 2m
· in clays it can be over 20m


Pore water and pore air pressure

Pore pressure
Between the ground surface and the top of the saturated zone, the soil will often be partially saturated, i.e. the pores contain a mixture of water and air. The pore pressure in a partially saturated soil consists of two components:
· porewater pressure = uw
· pore-air pressure = ua
Note that water is incompressible, but air is compressible. The combined effect is a complex relationship involving partial pressures and the degree of saturation of the soil. In Europe and other temperate climate countries most design states are associated with saturated conditions, and the study of partially saturated soils is considered to be a specialist subject.
 
 


Pore pressure in steady state seepage conditions

Pore pressure
In conditions of seepage in the ground there is a change in pore pressure. Consider seepage occurring between two points P and Q.

The hydralic gradient, i, between two points is the head drop per unit length between these points. It can be thougth of as the "potential" driving the water flow.
 
Hydralic gradient P-Q,  i = - dh
ds
  =  du
ds
.  
gw
Thus du = i . gw . ds

But in steady-state seepage, i = constant
Therefore the change in pore pressure due to seepage alone,  dus  =  i . gw . s
For seepage flow vertically downward, i is negative
For seepage flow vertically upward, i is positive.
 


Effective stress

Top
Ground movements and instabilities can be caused by changes in total stress (such as loading due to foundations or unloading due to excavations), but they can also be caused by changes in pore pressures (slopes can fail after rainfall increases the pore pressures).

In fact, it is the combined effect of total stress and pore pressure that controls soil behaviour such as shear strength, compression and distortion. The difference between the total stress and the pore pressure is called the effective stress:

effective stress = total stress - pore pressure

or s´ = s - u


Note that the prime (dash mark ´ ) indicates effective stress.
 
 


Terzaghi's principle and equation

Effective stress
Karl Terzaghi was born in Vienna and subsequently became a professor of soil mechanics in the USA. He was the first person to propose the relationship for effective stress (in 1936):

All measurable effects of a change of stress, such as compression, distortion and a change of shearing resistance are due exclusively to changes in effective stress. The effective stress s´ is related to total stress and pore pressure by s´ = s - u.

The adjective 'effective' is particularly apt, because it is effective stress that is effective in causing important changes: changes in strength, changes in volume, changes in shape. It does not represent the exact contact stress between particles but the distribution of load carried by the soil over the area considered.
 
 
 


Mohr circles for total and effective stress

Effective stress

Mohr circles can be drawn for both total and effective stress. The points E and T represent the total and effective stresses on the same plane. The two circles are displaced along the normal stress axis by the amount of pore pressure (sn = sn' + u), and their diameters are the same. The total and effective shear stresses are equal (t´ = t).
 
 


The importance of effective stress

Effective stress
The principle of effective stress is fundamentally important in soil mechanics. It must be treated as the basic axiom, since soil behaviour is governed by it. Total and effective stresses must be distinguishable in all calculations: algebraically the prime should indicate effective stress, e.g. s´

Changes in water level below ground (water table changes) result in changes in effective stresses below the water table. Changes in water level above ground (e.g. in lakes, rivers, etc.) do not cause changes in effective stresses in the ground below.

 

 


Changes in effective stress

Effective stress
In some analyses it is better to work in changes of quantity, rather than in absolute quantities; the effective stress expression then becomes:
Ds´ = Ds - Du

If both total stress and pore pressure change by the same amount, the effective stress remains constant. A change in effective stress will cause: a change in strength and a change in volume.
 
 


Changes in strength

Changes in effective stress
The critical shear strength of soil is proportional to the effective normal stress; thus, a change in effective stress brings about a change in strength.

Therefore, if the pore pressure in a soil slope increases, effective stresses will be reduced by Ds' and the critical strength of the soil will be reduced by Dt - sometimes leading to failure.

A seaside sandcastle will remain intact while damp, because the pore pressure is negative; as it dries, this pore pressure suction is lost and it collapses. Note: Sometimes a sandcastle will remain intact even when nearly dry because salt deposited as seawater evaporates slightly and cements the grains together.

 

 


Changes in volume

Changes in effective stress
Immediately after the construction of a foundation on a fine soil, the pore pressure increases, but immediately begins to drop as drainage occurs.

The rate of change of effective stress under a loaded foundation, once it is constructed, will be the same as the rate of change of pore pressure, and this is controlled by the permeability of the soil.

Settlement occurs as the volume (and therefore thickness) of the soil layers change. Thus, settlement occurs rapidly in coarse soils with high permeabilities and slowly in fine soils with low permeabilities.

 

 


Calculating vertical stress in the ground

Top
The worked examples here are designed to illustrate the principles and methods dealt with in Pore pressure, effective stress and stresses in the ground. The examples chosen are typical and simple.

 

 


Simple total and effective stresses

Calculating vertical stress
The figure shows soil layers on a site.
Unit weights are:
dry sand: gd = 16 kN/m³
saturated sand: gg = 20 kN/m³
(a) At the top of saturated sand (z = 2.0 m)
Vertical total stress sv = 16.0 x 2.0 = 32.0 kPa
Pore pressure u = 0
Vertical effective stress s´v = sv - u = 32.0 kPa
 
(b) At the top of the clay (z = 5.0 m)
Vertical total stress sv = 32.0 + 20.0 x 3.0 = 92.0 kPa
Pore pressure u = 9.81 x 3.0 = 29.4 kPa
Vertical effective stress s´v = sv - u  = 92.0 - 29.4 = 62.6 kPa


Effect of changing water table

Calculation of vertical stress
The figure shows soil layers on a site. The unit weight of the silty sand is 19.0 kN/m³ both above and below the water table. The water level is presently at the surface of the silty sand, it may drop or it may rise. The following calculations show the effects of this:
Water table





Stresses under foundations

Calculation of vertical stress

From an initial state, the stresses under a foundation are first changed by excavation, i.e. vertical stresses are reduced. After construction the foundation loading increases stresses. Other changes could result if the water table level changed.

The figure shows the elevation of a foundation to be constructed in a homogeneous soil. The change in thickness of the clay layer is to be calculated and so the initial and final effective stresses are required at the mid-depth of the clay.

Unit weights: sand above WT = 16 kN/m³, sand below WT = 20 kN/m³, clay = 18 kN/m³.

Calculations for
initial stresses
final stresses

 


Calculation of vertical stress

Short-term and long-term stresses

The figure shows how an extensive layer of fill will be placed on a certain site.

The unit weights are:
clay and sand = 20kN/m³ ,
rolled fill 18kN/m³ ,
assume water = 10 kN/m³.
Calculations are made for the total and effective stress at the mid-depth of the sand and the mid-depth of the clay for the following conditions: initially, before construction; immediately after construction; many years after construction.
 
 


Short-term and long-term stresses

Initially, before construction

Initial stresses at mid-depth of clay (z = 2.0m)
Vertical total stress
sv = 20.0 x 2.0 = 40.0kPa
Pore pressure
u = 10 x 2.0 = 20.0kPa
Vertical effective stress
s´v = sv - u = 20.0kPa

Initial stresses at mid-depth of sand (z = 5.0 m)
Vertical total stress
sv = 20.0 x 5.0 = 100.0 kPa
Pore pressure
u = 10 x 5.0 = 50.0 kPa
Vertical effective stress
s´v = sv - u = 50.0 kPa
 
 


Short-term and long-term stresses

Immediately after construction

The construction of the embankment applies a surface surcharge:
q = 18 x 4 = 72.0 kPa.

The sand is drained (either horizontally or into the rock below) and so there is no increase in pore pressure. The clay is undrained and the pore pressure increases by 72.0 kPa.

Initial stresses at mid-depth of clay (z = 2.0m)
Vertical total stress
sv = 20.0 x 2.0 + 72.0 = 112.0kPa
Pore pressure
u = 10 x 2.0 + 72.0 = 92.0 kPa
Vertical effective stress
s´v = sv - u = 20.0kPa
(i.e. no change immediately)

Initial stresses at mid-depth of sand (z = 5.0m)
Vertical total stress
sv = 20.0 x 5.0 + 72.0 = 172.0kPa
Pore pressure
u = 10 x 5.0 = 50.0 kPa
Vertical effective stress
s´v = sv - u = 122.0kPa
(i.e. an immediate increase)
 
 


Many years after construction

Short-term and long-term stresses

After many years, the excess pore pressures in the clay will have dissipated. The pore pressures will now be the same as they were initially.

Initial stresses at mid-depth of clay (z = 2.0 m)
Vertical total stress
sv = 20.0 x 2.0 + 72.0 = 112.0 kPa
Pore pressure
u = 10 x 2.0 = 20.0 kPa
Vertical effective stress
s´v = sv - u = 92.0 kPa
(i.e. a long-term increase)

Initial stresses at mid-depth of sand (z = 5.0 m)
Vertical total stress
sv = 20.0 x 5.0 + 72.0 = 172.0 kPa
Pore pressure
u = 10 x 5.0 = 50.0 kPa
Vertical effective stress
s´v = sv - u = 122.0 kPa
(i.e. no further change)

 


Steady-state seepage conditions

Calculation of vertical stress

The figure shows seepage occurring around embedded sheet piling.
In steady state, the hydraulic gradient,
i = Dh / Ds = 4 / ( 7 + 3 ) = 0.4
Then the effective stresses are:
s´A = 20 x 3 - 2 x 10 + 0.4 x 10 = 44 kPa
s´B = 20 x 3 - 2 x 10 - 0.4 x 10 = 36 kPa