Abstract
Deforestation and natural grassland conversion to agricultural land use constitute a major threat to soil and water conservation. This study aimed at assessing the status of land cover and land use (LCLU) in the Lake Kivu basin, and its related impacts in terms of soil erosion by water using the Universal Soil Erosion Equation (USLE) model. The results indicated that the Lake Kivu basin is exposed to soil erosion risk with a mean annual rate of 30 t·ha−1, and only 33% of the total non-water area is associated with a tolerable soil loss (≤10 t·ha−1·year−1). Due to both natural factors (abundant tropical precipitation and steep slopes) and anthropogenic activities without prior appropriate conservation practices, all land-use types—namely settlement, cropland, forestland, and grassland—are exposed to a severe mean erosion rate of 41 t·ha−1·year−1, 31 t·ha−1·year−1, 28 t·ha−1·year−1, and 20 t·ha−1·year−1, respectively. The cropland that occupied 74% of the non-water area in 2015 was the major contributor (75%) to the total annual soil loss in the Lake Kivu basin. This study showed that conservation practices in the cropland cells would result in a mean erosion rate of 7 t·ha−1·year−1, 18 t·ha−1·year−1, and 35 t·ha−1·year−1 for terracing, strip-cropping, and contouring, respectively. The adoption of terracing would be the best conservation practice, among others, that could reduce soil erosion in cropland areas up to about 23%. The erosion risk minimization in forests and grasslands implies an increase in overstorey canopy and understorey vegetation, and control of human activities such as fires, mining, soil compaction from domestic animals grazing, and so on. Soil erosion control in settled areas suggests, among other things, the revegetation of construction sites, establishment of outlet channels, rainfall water harvesting systems, and pervious paving block with grass.
Highlights
Forest clearance on slopes, accompanying the introduction of widespread agriculture, appears to be the most likely cause of the first landscape instability [1]
× K × Length and Steepness Factors (LS)) which cannot be controlled [26,74], while Figure 4b illustrates that the area is greatly exposed to soil erosion risk (R × K × LS × C × P) because of intensive agricultural land use and urbanisation without prior land conservation practices in an area that is naturally vulnerable to soil2016, erosion by PEER
The Universal Soil Erosion Equation (USLE) model and geographic information system (GIS) are prominent tools for soil erosion modelling with available geospatial data
Summary
Forest clearance on slopes, accompanying the introduction of widespread agriculture, appears to be the most likely cause of the first landscape instability [1]. These unsustainable land-use activities, together with natural factors such as abundant tropical rainfall and steep topography, increase soil erosion rates in the highland of tropical areas [2,3]. Mediterranean lands have suffered from changes in land uses that resulted in organic matter exhaustion, inappropriate ploughing, deforestation, erosion, soil degradation, salinization, and crusting Both traditional land use and human activities such as agriculture, grazing, mining, and charcoal and biomass production resulted in low soil fertility and highly eroded terrain [8,9].
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