posted on 2010-11-18, 12:34authored byIan Jefferson
Temperature changes occur in soils in a number of ways, e. g. landfill liners, around
buried services and during sampling. An experimental programme was conducted to
examine the effect of temperature (between 10 to 80 °C) on the volume change and
shear behaviour of saturated clays. Testing included Liquid Limit (cone penetrometer),
residual shear strength (modified Bromhead Ring Shear), laboratory vane shear ( at
moisture contents between the Liquid and Plastic Limits) and oedometer tests.
An extensive literature survey indicated that kaolinites and smectites would show
extremes of thermal behaviour. To examine this two artificially pure clays were tested:
English China Clay (a well crystallised kaolinite) and Wyoming Bentonite (a monovalent
smectite). To supplement this four British soils were tested: Keuper Marl,
Lower Lias Clay, London Clay and Oxford Clay. Full material data were obtained
coupled with careful control of stress and thermal histories.
It is concluded that two types of extreme thermal response exists: a thermomechanical
and a thermo-physicochemical change exhibited by kaolinite and smectite
respectively. The temperature sensitivity of clays relative to a particular parameter is
positively related to its specific surface area. A quick and repeatable method to
qualitatively assess this has been developed: the LUT method. Its advantages include
that no temperature calibrations are needed and it has a relatively large operating
temperature range, 10 to 80 °C having been successfully used.
The consolidation pressure (in the oedometer) needed to change the nature of a soil's
thermal response is negatively related to its specific surface area. This, it is postulated,
occurs at the same 'critical' contact stress for all clays, i. e. the interparticle threshold
stress at which a thermo-physicochemical response changes to a thermo-mechanical
one. This threshold stress occurs at a anisotropic consolidation pressure of 60 kPa for
a well crystallised kaolinite
, at 250 kPa for reconstituted London Clay and at 480 kPa
for a mono-valent smectite. Furthermore, greater parallel particle alignment or
reconstituting a sample enhances a soil's temperature sensitivity in the oedometer.
The thermal changes to consolidation and permeability coefficients can be typically
predicted by the corresponding change to the dynamic viscosity of water. Deviations
occur with smectites at normal stresses greater than 480 kPa, while for Keuper Marl
this occurred at normal stresses of 50 kPa and greater than 850 kPa.
Keuper Marl exhibits a greater temperature sensitivity of different parameters than
predicted by index tests. This is strongly dependent on consolidation pressure and
temperature. At elevated temperatures (>40 °C) and under increasing consolidation
pressure, ped units tend to collapse, but once the pressure is removed ped reformation
occurs. Thus knowledge of thermal and stress histories, coupled with full material
data, is essential to effectively predict temperature effects on the engineering behaviour
of soils with any degree of confidence.