Statistical Model Development for Estimating Soil Hydraulic Conductivity Through On-Site Investigations

Statistical Model Development for Estimating Soil Hydraulic Conductivity Through On-Site Investigations

In arid regions, irrigated agriculture is mainly dependent on groundwater. In Pakistan, 73% of agricultural land is directly or indirectly irrigated through groundwater. In Punjab (Pakistan), 1.2 million private tube wells are operating, mainly extracting 90% of the country’s groundwater. Most of th...

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Bibliographic Details
Main Authors: Muhammad Waleed, Muhammad Azhar Inam, Raffaele Albano, Abdul Samad, Hafiz Umar Farid, Muhammad Shoaib, Muhammad Usman Ali
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Hydrology
Subjects:
hydraulic conductivity
soil hydrological parameters
statistical model
borehole operations
soil hydrology
porosity and permeability
Online Access:https://www.mdpi.com/2306-5338/12/3/55
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Summary:In arid regions, irrigated agriculture is mainly dependent on groundwater. In Pakistan, 73% of agricultural land is directly or indirectly irrigated through groundwater. In Punjab (Pakistan), 1.2 million private tube wells are operating, mainly extracting 90% of the country’s groundwater. Most of these wells are poorly designed due to improper site investigations and poor estimations of the aquifer’s hydraulic parameters. As a result, most wells become dry, causing considerable financial losses to farmers. Hence, optimizing the well-designed parameters through proper soil investigations is essential. This research aims to develop a statistical model for estimating the hydraulic conductivity of soil through on-site investigation: five sites were selected in Multan (Pakistan), and seven samples were collected at each location from 3, 6, 9,12,15,18, and 21 m depth. For hydraulic conductivity, soil texture, and porosity, soil laboratory tests were carried out. Finally, a statistical model was developed using hydrological parameters such as average grain size distribution (<i>D</i><sub>50</sub>), uniformity coefficient (<i>U</i>), and porosity (<i>n</i>). Statistically computed hydraulic conductivity was verified with experimentally measured and empirically derived hydraulic conductivity. Statistically measured hydraulic conductivity showed closer agreement with experimentally measured hydraulic conductivity than the empirically measured hydraulic conductivity: root mean square error (RMSE), correlation coefficient (<i>Cc</i>), and mean absolute error (<i>MAE</i>) are, respectively, equal to 0.013, 0.93, and 0.011.
ISSN:2306-5338

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