Changes in Thornthwaite Moisture Index and Reactive Soil Movements under Current and Future Climate Scenarios—A Case Study

Karim, Rajibul; Rahman, M.F.; Nguyen, Hoang Bao Khoi; Cameron, D. A.; Iqbal, Asif; Ahenkorah, Isaac

doi:10.3390/en14206760

Cited by 7 publications

(8 citation statements)

References 34 publications

(42 reference statements)

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“…Soil slopes, i.e., cuttings or embankments, are an integral part of our transport network. Since the variability of material quality is common in soils, especially for silty or clayey soils (Karim et al, 2011;Devkota et al, 2022;Karim et al, 2022), the uncertainty on the stability of these slopes is an inherent challenge (Griffiths, 1982;Huang et al, 2006;Gould et al, 2011;Kasama and Whittle, 2011;Karim et al, 2021). Further, the mechanics for slope stability analysis that involves the conventional limit state approach uses simplifications and approximations, which adds to the uncertainty of their design.…”

Section: Introductionmentioning

confidence: 99%

Effect of soil anisotropy and variability on the stability of undrained soil slope

Nguyen

Rahman²,

Karim³

2023

Front. Built Environ.

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Soil is a naturally heterogeneous material and can show significant spatial variation in strength and other properties. For silty and clayey soils, these variations are often more pronounced. Despite such variation, many past studies considered these soils as homogeneous and only considered a single set of soil parameters. This may lead to underestimation of the failure potential of geo-structure such as natural slopes, water retaining dams, retaining walls, etc. A finite element method considering soil variability should be an ideal tool to investigate the behaviour of these soils. This study adopted a 2D random finite element method to evaluate the effect of such variability on slope stability. The spatial variability was implemented by using the coefficient of variation (COV) and the spatial correlation length (θ) for cohesion. It was found that the soil slope with higher COV would have a higher chance of failure, whereas the soil slope with less COV might not show any failure. In addition, the soil with a higher θ, in general, show less potential of failure. In the literature, most studies considered an isotropic condition for the soil, i.e., θ in x and y directions are the same θx = θy, which is not realistic. Therefore, the soil anisotropy (i.e., θx ≠ θy) was considered carefully in this study. It was found that the probability of failure for anisotropic soil might be significantly higher than the isotropic soil.

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Section: Introductionmentioning

confidence: 99%

Effect of soil anisotropy and variability on the stability of undrained soil slope

Nguyen

Rahman²,

Karim³

2023

Front. Built Environ.

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“…Mitchell [28] showed that it is possible to account for expansive soil movement in design using empirical methods without heavily relying on experience. Later works [1,[30][31][32][33][34] highlighted the importance of better understanding the influence of atmospheric boundary interaction and changes in climate on the behaviour of shallow-depth structures on/in expansive soils. Several previous works have related climate with depth of suction change, e.g., Hu et al [35], Davenport [36], Walsh et al [37] and Fityus et al [38] generated depth of suction change (H s ) databases for different areas of Australia.…”

Section: Introductionmentioning

confidence: 99%

Influence of Weather, Soil Variability, and Vegetation on Seasonal Ground Movement: A Field Study

Cameron,

Karim,

Johnson

et al. 2023

Geotechnics

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Expansive soils change volume due to changes in moisture content, which results in ground movement. Lightweight shallow-depth structures such as pavements, residential footings, and pipelines can suffer distress as they face additional stresses from the moving ground. The soil reactivity (the ability of soil to expand or contract due to change in moisture content) and the interactions at the soil-atmosphere-vegetation boundary are two of the major contributing factors to the ground movement. The current methodology used in design to account for ground movement is based on limited field and laboratory observations. Aiming at a better understanding of the interaction at the soil-atmosphere-vegetation boundary and its correlation with ground movement, this paper presents results from a field study. The research site was located in a semi-arid climate area and consisted of moderately to highly reactive clay soils. Part of the site was vegetated with mature trees, and part was occupied by grass. The order of 10 s of mm difference was observed in the magnitude of movement across the site owing to site soil variability as well as differences in vegetation. The areas with large trees showed relatively lower ground movement over the study period compared to the area occupied by grass, which was attributed to the microclimate created by the tree canopy and the already established deeper drying of the soil near the trees.

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“…The climate in Australia and around the world will continue to change in the coming decades, leading to significant socio-economic impacts [11]. Accounting for all climate variables can be a complex exercise, and changes in rainfall and temperature have been considered as the primary variables in most studies that investigated the soil-atmospheric boundary interaction, especially the ones looking at the effect of climate change [12][13][14][15][16][17]. Changes in temperature and rainfall may affect the behaviour of geotechnical infrastructure.…”

Section: Introductionmentioning

confidence: 99%

“…Depending on the geolocation, local climate, expected future changes in the climate, and structure type, these effects can vary. Although soil-atmospheric boundary interactions have been an active area of research over the last two decades, limited attention has been paid to reactive soil movement and its interaction with structures [16]. This problem is likely to worsen because of climate change.…”

Section: Introductionmentioning

confidence: 99%

Accounting for Expansive Soil Movement in Geotechnical Design—A State-of-the-Art Review

et al. 2022

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Lightweight structures built on expansive soils are susceptible to damage caused by soil movement. Financial losses resulting from the improper design of structures on expansive soils can be significant. The interactions and failure mechanisms of different geotechnical structures constructed on such soils differ depending on the structure type, site characteristics, and climatic conditions, as the behaviour of expansive soils is influenced by moisture variations. Therefore, the performance of different geotechnical structures (e.g., lightweight footings for residential buildings) is expected to be adversely affected by climate change (especially rainfall and temperature change), as geotechnical structures are often designed to have a service life of 50–100 years. Some structures may even fail if the effect of climate change is not considered in the present design. This review aims to provide insights into problems associated with expansive soils that trigger the failure of lightweight structures, including current investigations and industry practices. This review recognises that although the soil moisture conditions govern expansive soil behaviour, limited studies have incorporated the effect of future climate changes. In addition, this review identifies the need to improve the current Australian design practice for residential footings through the inclusion of more site-specific investigations and expected climate changes.

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Changes in Thornthwaite Moisture Index and Reactive Soil Movements under Current and Future Climate Scenarios—A Case Study

Cited by 7 publications

References 34 publications

Effect of soil anisotropy and variability on the stability of undrained soil slope

Effect of soil anisotropy and variability on the stability of undrained soil slope

Influence of Weather, Soil Variability, and Vegetation on Seasonal Ground Movement: A Field Study

Accounting for Expansive Soil Movement in Geotechnical Design—A State-of-the-Art Review

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