Abstract
Soil erosion determines landforms, soil formation and distribution, soil fertility, and land degradation processes. In arid and semiarid ecosystems, soil erosion is a key process to understand, foresee, and prevent desertification. Addressing soil erosion throughout watersheds scales requires basic information to develop soil erosion control strategies and to reduce land degradation. To assess and remediate the non-sustainable soil erosion rates, restoration programs benefit from the knowledge of the spatial distribution of the soil losses to develop maps of soil erosion. This study presents Support Vector Machine (SVM), Random Forest (RF), and adaptive boosting (AdaBoost) data mining models to map soil erosion susceptibility in Kozetopraghi watershed, Iran. A soil erosion inventory map was prepared from field rainfall simulation experiments on 174 randomly selected points along the Kozetopraghi watershed. In previous studies, this map has been prepared using indirect methods such as the Universal Soil Loss Equation to assess soil erosion. Direct field measurements for mapping soil erosion susceptibility have so far not been carried out in our study site in the past. The soil erosion rate data generated by simulated rainfall in 1 m2 plots at rainfall rate of 40 mmh−1 was used to develop the soil erosion map. Of the available data, 70% and 30% were randomly classified to calibrate and validate the models, respectively. As a result, the RF model with the highest area under the curve (AUC) value in a receiver operating characteristics (ROC) curve (0.91), and the lowest mean square error (MSE) value (0.09), has the most concordance and spatial differentiation. Sensitivity analysis by Jackknife and IncNodePurity methods indicates that the slope angle is the most important factor within the soil erosion susceptibility map. The RF susceptibility map showed that the areas located in the center and near the watershed outlet have the most susceptibility to soil erosion. This information can be used to support the development of sustainable restoration plans with more accuracy. Our methodology has been evaluated and can be also applied in other regions.
Highlights
Soil erosion determines landforms [1,2], soil distribution [3,4], soil fertility [3,5], and land degradation processes [6,7]
The erosion susceptibility maps were prepared by applying Support Vector Machine (SVM), Random Forest (RF) and AdaBoost models
The results showed that in each of the studies in the region found that the whole watershed was affected by soil erosion [79], but our three models used in this research, the soils that have the highest susceptibility to soil erosion and research enables a spatial differentiation based on the rainfall simulation experiments
Summary
Soil erosion determines landforms [1,2], soil distribution [3,4], soil fertility [3,5], and land degradation processes [6,7]. An improved understanding of soil erosion processes, rates, and spatiotemporal variability supports the development of soil erosion control strategies and the mitigation of land degradation [10,11]. Soil erosion refers to the process of detachment, transport, and sedimentation of particles [14]. Runoff is the main cause of soil particle transport along the slopes. Another relevant mechanism of soil erosion is splash erosion, which is important in areas with low vegetation cover [14]
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