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1. Investigating Sub-soil Moisture Variation of Engineered Turf Cover for Landfills Through Field Instrumentation

   Md. Jobair Bin Alam, Maalvika Aggarwal (March 2023, Atlantis highlights in engineering)

   S. Javankhoshdel and Y. Abolfazlzadeh (Ed.)

   Understanding the moisture distribution pattern and associated suction variability of soil in response to environmental loading (e.g., precipitation, temperature) is important. However, there is a lack of understanding of the spatial variability of moisture and suction in different final cover systems. In this study, the spatial correlations between soil moisture and suction data from field instrumentation are examined using Spearman’s rank correlation test of three different types of landfill final cover systems: evapotranspiration (ET) cover, conventional clay cover, and engineered turf cover, under identical atmospheric conditions. In addition, box and whiskers plots were used to investigate the distribution of the field-measured data under environmental fluctuation. As observed from the box plot, soil moisture displayed maximum spatial heterogeneity in clay cover and very less in the engineered turf cover under identical environmental conditions. The ET cover exhibited a very strong spatial correlation of moisture and suction as indicated by the highly significant Spearman’s rank correlations (rs) ranging from −0.88 to −0.93. The clay cover showed a strong to moderate correlation (−0.51 < rs < −0.74) between the spatial distribution of moisture and suction. On the other hand, the engineered turf cover displayed poor agreement of the spatial moisture-suction distribution implying the soil under the engineered turf is relatively non-responsive under environmental variability compared to clay and ET cover. The preliminary findings from this study showed engineered turf’s capacity to maintain more moisture stability of the turf under the humid subtropical climate than other landfill covers. 

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2. Probabilistic Analysis of In Situ Soil Water Characteristic Curve Using Kernel Density Estimation

   https://doi.org/10.1061/9780784485354.027  

   Alam, Md. Jobair; Aggarwal, Maalvika; Rahman, Naima (February 2024, American Society of Civil Engineers)

   T. Matthew Evans, Ph.D. Nina Stark (Ed.)

   Soil water characteristic curve (SWCC) which describes the relationship between water content and matric suction is important to analyzing unsaturated soil behavior. Because of the degree of uncertainty in field conditions due to climatic variability and soil heterogeneities, it becomes necessary to probabilistically characterize the SWCC. A satisfactory probabilistic characterization of field-based SWCCs requires a substantial data pair of water content and suction and their distribution characteristics. In this study, the kernel density estimate (KDE) approach was applied to water content and suction data measured from field-installed co-located sensors of a compacted clay bed to (1) determine the modality of water content and suction distribution and their constitutive relationship at variable weather conditions and (2) demonstrate the importance of probabilistic analysis of SWCC. The Gaussian function was used in the KDE analysis. A moisture sensor and soil water potential sensor were juxtaposed at 0.3 m depth of the 3 m × 3 m compacted clay bed to collect the water content and suction data and determine their distribution under the field condition. The density plots of both water content and suction at 0.3 m depth exhibited multimodal distribution due to the uneven distribution of climatic events. The KDE reasonably identified the air entry value, saturated moisture content, and residual moisture content in the field conditions, which were validated with field-based SWCC plots. The study showed that probabilistic analysis better interprets the realistic scenarios of field unsaturated soil behavior. 

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3. Probability Distribution of Soil Suction of Engineered Turf Cover and Compacted Clay Cover

   https://doi.org/10.1051/e3sconf/202338224002  

   Alam, Md Jobair; Aggarwal, Maalvika (January 2023, E3S Web of Conferences)

   Bardanis, M. (Ed.)

   It is unlikely to predict the distribution of soil suction in the field deterministically. It is well established that there are various sources of uncertainty in the measurement of matric suction, and the suction measurements in the field are even more critical because of the heterogeneities in the field conditions. Hence it becomes necessary to probabilistically characterize the suction in the field for enhanced reliability. The objective of this study was to conduct a probabilistic analysis of measured soil suction of two different test landfill covers, compacted clay cover (CC) and engineered turf cover (ETC), under similar meteorological events. The size of the two test landfill covers was 3 m × 3 m (10 ft. × 10 ft.) and 1.2 m (4ft.) in depth. The covers were constructed by excavating the existing subgrade, placing 6-mil plastic sheets, and backfilling the excavated soil, followed by layered compaction. Then the covers were instrumented identically with soil water potential sensors up to specified depths. One of the covers acted as the CC, and the other cover was ETC. In ETC, engineered turf was laid over the compacted soil. The engineered turf consisted of a structured LLDPE geomembrane overlain by synthetic turf (polyethylene fibers tufted through a double layer of woven polypropylene geotextiles). The sensors were connected to an automated data logging system and the collected data were probabilistically analyzed using the R program. There were significant inconsistencies in the descriptive statistical parameters of the measured soil suction at both covers under the same climatic conditions. Soil suction measured in the field ranged between almost 12 to 44 kPa in ETC, while it was in the range of almost 1 to 2020 kPa in the CC. The histogram and quantile-quantile (Q-Q) plot showed the data to be non-normally distributed in the field. A heavy-tailed leptokurtic (Kurtosis=13) distribution of suction was observed in the ETC with substantial outliers. In contrast, the suction distribution in CC was observed skewed to the right containing a thinner tail indicating an almost platykurtic distribution. The distribution of suction in the field under engineered turf was observed to be reasonably consistent with time compared to bare soil under the same meteorological events. The results obtained from this study revealed the engineered turf system to be an effective barrier to inducing changes in soil suction against climatic events. 

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4. Investigating Moisture Distribution Characteristics of Different Landfill Cover Soil at Shallow Depths Using Gaussian Distribution Analysis

   https://doi.org/10.1061/9780784485330.063  

   Alam, Md. Jobair; Aggarwal, Maalvika; Ray, Ram; Rahman, Naima (February 2024, American Society of Civil Engineers)

   T. Matthew Evans, Ph.D. Nina Stark (Ed.)

   One of the major purposes of landfill final covers is to minimize the infiltration of precipitation into the underlying waste. Deployment of conventional clay covers, geosynthetic clay liner, evapotranspiration (ET) covers, etc., has mostly been in practice to achieve the purposes. However, they have their shortcomings in the full attainment of the goals. In recent years, engineered turf has been introduced for landfill closure as a precipitation barrier to enhance cover performance. However, the field demonstration of engineered turf cover as the infiltration barrier is very limited. Soil moisture being one of the performance indicators of landfill covers, the objective of this study was to investigate moisture distribution characteristics of three distinct prototype landfill final cover systems: ET cover, compacted clay cover, and engineered turf cover, under in a humid subtropical climatic region. All the test covers (3 m × 3 m) were constructed side by side and were instrumented with moisture sensors at shallow depth (0.3 m depth). Descriptive statistics and histograms were used to summarize the features of the moisture distribution. Gaussian distribution theorem was used to investigate the spread out of the moisture data. In addition, the original moisture data were transformed to the standard normal distribution for a consistent framework for investigating the moisture variability of different covers. The analysis showed that 95% of the data were clustered around 0.173 to 0.238 m3/m3 at 0.3 m depth of engineered turf cover. On the contrary, the other two covers’ soil had a similar wider spread out of moisture data ranging approximately from 0.041 to 0.34 m3/m3. Results obtained from this study indicated the efficiency of engineered turf cover as an effective barrier to precipitation. 

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5. Evaluation of the Impact of Climate Variability on the Soil-Water Characteristics Curve

   https://doi.org/10.1177/03611981241243327  

   Rahman, Fariha; Khan, Md Fahimuzzaman; Nahian, Audrika; Khan, Sadik; Amini, Farshad (November 2024, Transportation Research Record: Journal of the Transportation Research Board)

   The hydro-mechanical behavior of unsaturated soil, particularly expansive soil, is influenced significantly by cyclic wetting and drying. Understanding the soil parameters is crucial when evaluating the performance of infrastructures constructed on expansive clay. As a result of extreme rainfall events, highway slopes containing highly expansive Yazoo clay in Mississippi, U.S., become vulnerable to volume change. The phenomenon creates perched water zones within the slopes and poses a risk of slope failure. The soil-water characteristic curve (SWCC) defines the relationship between water content and soil suction, which can be obtained from different laboratory procedures. However, conventional laboratory methods have some limitations. To address this, various analytical and predictive models have been developed, but they can only offer estimates based on soil characteristics and lack seasonal variations occurring in field conditions. Studying seasonal SWCC through field measurements can help understand soil responses to changing moisture conditions. The current study utilized field data from six highway slopes in Mississippi and classified the data into different seasons: spring, summer, and fall. After obtaining van Genuchten parameters from the fitted curve for each season, the finite element method was applied to evaluate the parameters for accurate numerical analysis of infrastructures containing expansive clay. The study observed the variations in flow parameters with seasonal change that cannot be achieved when data from only one season is considered. The findings underscore the importance of field instrumentation data for developing SWCC and the significance of seasonal flow parameters in infrastructure design. 

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