A void ratio dependent water retention curve model including hydraulic hysteresis

Past experimental evidence has shown that Water Retention Curve (WRC) evolves with mechanical stress and structural changes in soil matrix. Models currently available in the literature for capturing the volume change dependency of WRC are mainly empirical in nature requiring an extensive experimenta...

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Bibliographic Details
Main Authors: Pasha, Amin Y., Khoshghalb, Arman, Khalili, Nasser
Format: Conference Proceeding
Language:English
Subjects:
Compacted soils
Deformation
Dependence
Drying
Empirical analysis
Evolution
Experimental data
Expulsion
Formability
Hydraulics
Hysteresis
Hysteresis models
Mathematical models
Parameter identification
Pore size
Pore size distribution
Porosity
Porous media
Retention
Scanning
Size distribution
Soil compaction
Soil mechanics
Void ratio
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Summary:Past experimental evidence has shown that Water Retention Curve (WRC) evolves with mechanical stress and structural changes in soil matrix. Models currently available in the literature for capturing the volume change dependency of WRC are mainly empirical in nature requiring an extensive experimental programme for parameter identification which renders them unsuitable for practical applications. In this paper, an analytical model for the evaluation of the void ratio dependency of WRC in deformable porous media is presented. The approach proposed enables quantification of the dependency of WRC on void ratio solely based on the form of WRC at the reference void ratio and requires no additional parameters. The effect of hydraulic hysteresis on the evolution process is also incorporated in the model, an aspect rarely addressed in the literature. Expressions are presented for the evolution of main and scanning curves due to loading and change in the hydraulic path from scanning to main wetting/drying and vice versa as well as the WRC parameters such as air entry value, air expulsion value, pore size distribution index and slope of the scanning curve. The model is validated using experimental data on compacted and reconstituted soils subjected to various hydro-mechanical paths. Good agreement is obtained between model predictions and experimental data in all the cases considered.
ISSN:2267-1242
2555-0403
2267-1242
DOI:10.1051/e3sconf/20160911010