Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Constitutive model of structural alteration and swelling behavior for Old Alluvium
Abstract We describe a constitutive model for the compression and swelling behavior of Old Alluvium, a material with a complex microstructure characterized by Fe-oxides cementation and silt-sized aggregates of swelling clay minerals. Compression loading of this material breaks down the aggregate structure, altering the mineralogy, particle fracture properties, and physicochemical properties. We use cation exchange capacity as a measurable proxy to represent the microstructural evolution that can be linked to changes in compressibility with consolidation stress. At load reversal, the value of cation exchange capacity affects the microscale swelling pressures associated with osmotic repulsion between platelets of expansive nontronite. The micro- and macro-scale stiffnesses are linked through a parameter that relates the disjoining pressure to the macroscopic swelling pressure, and an interaction function. By relating macroscopic strains to microscale osmotic repulsion between expansive clay platelets, the proposed model builds directly on the physicochemical characteristics of the material and achieves a more consistent physical basis for describing the unloading response than prior formulations. We illustrate how the model can provide a framework for interpreting how engineering properties vary vertically with the state of weathering in the Old Alluvium soil profile. This approach should find broader application for other piedmont, transported, residual soils.
Highlights Constitutive framework describes compression and swelling behavior of Old Alluvium. Model captures the effect of structural alteration on the macroscopic behavior. Cation exchange capacity relates compressibility to physico-chemical changes. Macroscopic swelling pressure is linked to disjoining pressure. Framework captures vertical variation of engineering properties due to weathering.
Constitutive model of structural alteration and swelling behavior for Old Alluvium
Abstract We describe a constitutive model for the compression and swelling behavior of Old Alluvium, a material with a complex microstructure characterized by Fe-oxides cementation and silt-sized aggregates of swelling clay minerals. Compression loading of this material breaks down the aggregate structure, altering the mineralogy, particle fracture properties, and physicochemical properties. We use cation exchange capacity as a measurable proxy to represent the microstructural evolution that can be linked to changes in compressibility with consolidation stress. At load reversal, the value of cation exchange capacity affects the microscale swelling pressures associated with osmotic repulsion between platelets of expansive nontronite. The micro- and macro-scale stiffnesses are linked through a parameter that relates the disjoining pressure to the macroscopic swelling pressure, and an interaction function. By relating macroscopic strains to microscale osmotic repulsion between expansive clay platelets, the proposed model builds directly on the physicochemical characteristics of the material and achieves a more consistent physical basis for describing the unloading response than prior formulations. We illustrate how the model can provide a framework for interpreting how engineering properties vary vertically with the state of weathering in the Old Alluvium soil profile. This approach should find broader application for other piedmont, transported, residual soils.
Highlights Constitutive framework describes compression and swelling behavior of Old Alluvium. Model captures the effect of structural alteration on the macroscopic behavior. Cation exchange capacity relates compressibility to physico-chemical changes. Macroscopic swelling pressure is linked to disjoining pressure. Framework captures vertical variation of engineering properties due to weathering.
Constitutive model of structural alteration and swelling behavior for Old Alluvium
Nikolinakou, Maria A. (Autor:in) / Whittle, Andrew J. (Autor:in)
Engineering Geology ; 293
26.07.2021
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Consolidation properties and structural alteration of Old Alluvium
| Springer Verlag | 2022
Characterization of gravelly alluvium
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Characterization of gravelly alluvium
| British Library Online Contents | 2016
| Engineering Index Backfile | 1930