Shah, Syed Samran Ali, Turrakheil, Kanishka and Naveed, Muhammad ORCID: https://orcid.org/0000-0002-0923-4976 (2024) Impact of Wetting and Drying Cycles on the Hydromechanical Properties of Soil and Implications on Slope Stability. Atmosphere, 15 (11). p. 1368.
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Abstract
The soil-based infrastructure is the backbone of the global economy, connecting people, enhancing quality of life, and promoting health and safety. However, its vulnerabilities are becoming apparent due to climate change, mainly through frequent wetting and drying (wd) cycles. Despite few studies in the past, research showing the stability of flood embankments in the long term, incorporating the impact of wetting and drying cycles on the hydromechanical characteristics of soil, is scarce. This study aimed to assess the impact of controlled wd cycles on the hydromechanical properties of clay and silty sand soils and its implications for the stability of a typical flood embankment. Volumetric changes were monitored during the wd cycles. The soil water characteristic curve (SWCC), saturated hydraulic conductivity (ksat), effective cohesion (c′), and effective angle of internal friction (ϕ′) were measured at 1 and 10 wd cycles. The results indicated that the 10 wd cycles decreased the saturated moisture content and resulted in a flatter SWCC compared to the 1 wd cycle for clayey soil. The ksat value was also significantly higher at 10 wd cycles than 1 wd cycle for clayey soil. An insignificant difference was found in both the SWCC and ksat at 1 and 10 wd cycles for silty sand soil. The ϕ′ value for the clayey soil decreased from 28.5 to 20.1 as the wd cycles increased from 1 to 10, while c′ remained unchanged at 10 kN/m2. On the other hand, for the silty sand soil, ϕ′ increased from 34.6 to 37.5 with an increase in wd cycles from 1 to 10, and c′ remained constant at 1 kN/m2. Numerical modelling of transient water flow coupled with a slope stability analysis revealed that the stability of a flood embankment depends on the evolution of soil hydromechanical properties due to wd cycles and the duration of flooding. These findings underscore the need for proactive measures to mitigate landslide risks in regions prone to frequent wd cycles, thereby ensuring the safety and resilience of slopes and associated infrastructure.
Item Type: | Article |
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Identifier: | 10.3390/atmos15111368 |
Keywords: | wetting–drying cycles; soil water characteristics; saturated hydraulic conductivity; shear strength of soil; slope stability analysis |
Subjects: | Construction and engineering |
Depositing User: | Muhammad Naveed |
Date Deposited: | 02 Dec 2024 15:13 |
Last Modified: | 05 Dec 2024 14:45 |
URI: | https://repository.uwl.ac.uk/id/eprint/12948 |
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