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Abstract The determination of the small strain shear modulus $ G_{0} $ of gravels is a very important issue, both under monotonic or cyclic loading conditions. In the paper, the results of a series of triaxial tests carried out in a large apparatus on frozen (undisturbed) specimens of gravel are presented, along with the description of a new experimental device developed to measure the velocity of the shear waves $ V_{s} $. During undrained cyclic tests, $ V_{s} $ values were measured before and after liquefaction, to analyse the effect of this peculiar stress history on the small strain stiffness $ G_{0} $ of coarse grained soils. The small strain shear stiffness decreases as pore pressure in the specimen builds up. However, even in tests in which liquefaction was attained during the cyclic loading phase, $ G_{0} $ showed to depend only on the current value of the effective stress: its values become smaller than the initial one (before cyclic loading was applied) but not nil, depending on the transient value of the pore pressure and therefore of the effective stress. Furthermore, the experimental results showed that, since there was no sudden drop of $ G_{0} $ upon liquefaction triggering, the gravel did not have a structure which significantly affected its mechanical behaviour.
Abstract The determination of the small strain shear modulus $ G_{0} $ of gravels is a very important issue, both under monotonic or cyclic loading conditions. In the paper, the results of a series of triaxial tests carried out in a large apparatus on frozen (undisturbed) specimens of gravel are presented, along with the description of a new experimental device developed to measure the velocity of the shear waves $ V_{s} $. During undrained cyclic tests, $ V_{s} $ values were measured before and after liquefaction, to analyse the effect of this peculiar stress history on the small strain stiffness $ G_{0} $ of coarse grained soils. The small strain shear stiffness decreases as pore pressure in the specimen builds up. However, even in tests in which liquefaction was attained during the cyclic loading phase, $ G_{0} $ showed to depend only on the current value of the effective stress: its values become smaller than the initial one (before cyclic loading was applied) but not nil, depending on the transient value of the pore pressure and therefore of the effective stress. Furthermore, the experimental results showed that, since there was no sudden drop of $ G_{0} $ upon liquefaction triggering, the gravel did not have a structure which significantly affected its mechanical behaviour.
Small Strain Shear Modulus of Undisturbed Gravelly Soils During Undrained Cyclic Triaxial Tests
2013
Article (Journal)
English
Small Strain Shear Modulus of Undisturbed Gravelly Soils During Undrained Cyclic Triaxial Tests
| Online Contents | 2013
Small Strain Shear Modulus of Undisturbed Gravelly Soils During Undrained Cyclic Triaxial Tests
| Springer Verlag | 2013
Small Strain Shear Modulus of Undisturbed Gravelly Soils During Undrained Cyclic Triaxial Tests
| British Library Online Contents | 2013
Undrained cyclic resistance of undisturbed gravelly soils
| Online Contents | 2012
Undrained cyclic resistance of undisturbed gravelly soils
| British Library Online Contents | 2012