Soil-particle and pore orientations during drained and undrained shear of a cohesive sandy siltclay soil

The pore size, shape and orientation of an illite-dominant clay were mapped during one-dimensional compression, using mercury intrusion porosimetry, scanning electron microscopy and gas adsorption. The total porosity was found to spread over the three IUPAC classes of pores sizes: micropores (below 2 nm), mesopores (2-50 nm) and macropores (above 50 nm), and all three pore classes were observed during the compression. The clay structure is aggregated, with visible inter-aggregate pores (about 80% of the total porosity), the remaining intra-aggregate pores of size approximately equal to the thickness of illite platelets (50-100 layers). During compression the largest pores first collapsed, followed by a progressive collapse, in an orderly manner, of smaller and smaller pores. MIP data suggest that the macroscopic deformation mainly translates at the pore scale into changes of inter-aggregate porosity, while intra-aggregate pores spread over the micro- to mesopore size range. Gas adsorption tests show that the volume of intra-aggregate pores decreases with loading, probably due to rearrangement of particles composing the aggregates, while the specific surface area reduces. Examination of the pores’ orientation on both vertical and horizontal planes confirms a preferential orientation of pores normal to the loading direction, with a gradual flattening of the pores.

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“…Pires et al, 2008) but with also some recent examples in soil mechanics (e.g. Cetin and Söylemez, 2004;Gao et al, 2020).…”

Section: Introductionmentioning

confidence: 96%

Pore changes in an illitic clay during one-dimensional compression

Baudet

Delage

et al. 2023

Géotechnique

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“…Most of the samples did not have a clear or pronounced failure point exhibiting strain-hardening behavior, which is typical of cohesive soils like clays. Here, the failure point was taken as the stress corresponding to 15% shear strain as recommended by [54,55], and ASTM D 3080-04 [45]. Figure 8 also shows the vertical (volumetric) deformation changes as the samples were sheared under the selected normal pressures.…”

Section: Resultsmentioning

confidence: 99%

Improvement of Geotechnical Properties of Clayey Soil Using Biopolymer and Ferrochromium Slag Additives

Çetin,

Bağrıaçık,

Annagür

et al. 2024

Polymers

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The geotechnical properties of clay soil and its mixtures with different proportions (0.75%, 0.85%, 1%, and 1.15%) of Agar Gum biopolymer and Ferrochromium Slag (0.25%, 0.50%, 0.75%, and 1%), having various curing times and freeze-thaw cycles, were studied through a series of soil mechanical tests to investigate possibilities to improve its undesired/problematic plasticity, compaction, and shear strength characteristics. The results revealed that treatment with an optimal ratio of 1% Agar Gum and 1% Ferrochromium Slag alone, as well as together with, improved the geotechnical properties of the clay soil considerably. Both the unconfined and shear strength properties, along with the cohesion and internal friction angle, increased as much as 47 to 173%, depending on the curing time. The higher the curing time, the higher the shear strength, cohesion, and internal friction angle are up to 21 days. Deteriorating the soil structure and/or fabric, freeze-thaw cycles, however, seem to have an adverse effect on the strength. The higher the freeze-thaw cycle, the lower the shear strength, cohesion, and internal friction angle. Also, some improvements in the plasticity and compaction properties were determined, and environmental concerns regarding Ferrochromium Slag usage have been addressed.

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“…The hysteresis curve of the soil mass is the basis of studying the dynamic triaxial characteristics. The characteristic dynamic parameters of the soil mass, including the dynamic elastic modulus and the damping ratio, could be obtained by the quantitative characteristic analysis [14] of the hysteresis curves.…”

Section: Change Rules Of Dynamic Elastic Modulusmentioning

confidence: 99%

Research on Dynamic Stress–Strain Change Rules of Rubber-Particle-Mixed Sand

et al. 2022

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We conducted GDS dynamic triaxial tests to study the change rules of the hysteresis curve morphology, axial strain, dynamic elastic modulus, and damping ratio of waste tire rubber-mixed sand-based subgrade model samples with different rubber particle sizes, rubber mixing amounts, and loading times. The research revealed the developmental rule of the hysteresis curves of waste tire rubber-mixed-sand samples under cyclic loading. From the analyses and comparison of the dynamic stress–strain change rules of rubber-particle-mixed-sand samples under different test conditions, it was concluded that the dynamic elastic modulus and shear stiffness of rubber-mixed-sand samples were smaller than those of pure sand samples under cyclic loading while their damping ratios were greater than that of pure sand samples, promoting vibration resistance and reduction to a larger extent. Therefore, this conclusion is of guiding significance for engineering practice.

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Soil-particle and pore orientations during drained and undrained shear of a cohesive sandy siltclay soil

Cited by 19 publications

References 9 publications

Pore changes in an illitic clay during one-dimensional compression

Pore changes in an illitic clay during one-dimensional compression

Improvement of Geotechnical Properties of Clayey Soil Using Biopolymer and Ferrochromium Slag Additives

Research on Dynamic Stress–Strain Change Rules of Rubber-Particle-Mixed Sand

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Soil-particle and pore orientations during drained and undrained shear of a cohesive sandy siltclay soil

Cited by 19 publications

References 9 publications

Pore changes in an illitic clay during one-dimensional compression

Pore changes in an illitic clay during one-dimensional compression

Improvement of Geotechnical Properties of Clayey Soil Using Biopolymer and Ferrochromium Slag Additives

Research on Dynamic Stress–Strain Change Rules of Rubber-Particle-Mixed Sand

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Soil-particle and pore orientations during drained and undrained shear of a cohesive sandy siltclay soil