Global Journal of Earth and Environmental Science

GLOBAL JOURNAL OF EARTH AND ENVIRONMENTAL SCIENCE
Integrity Research Journals

ISSN: 2636-6002
Model: Open Access/Peer Reviewed
DOI: 10.31248/GJEES
Start Year: 2016
Email: gjees@integrityresjournals.org

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Spatial soil loss risk assessment for priority intervention using GIS and remote sensing techniques: A case of Neri Watershed Southwestern Ethiopia

https://doi.org/10.31248/GJEES2021.104   |   Article Number: 241DE6863   |   Vol.6 (3) - August 2021

Received Date: 25 July 2021   |   Accepted Date: 24 August 2021  |   Published Date: 30 August 2021

Authors:  Abebe Hegano* and Awdenegest Moges

Keywords: Neri watershed, RUSLE model, soil loss, Tolerable soil loss.

ABSTRACT

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Soil loss by runoff is a severe and continuous ecological problem in Neri watershed. It affects agricultural production, drinking water quality, ecosystem health, and landscape aesthetics. This study was conducted to assess spatial risk of soil by estimating the average annual soil loss, and creating a soil erosion hazard map for this watershed. Revised Universal Soil Loss Equation (RUSLE) model supported by a GIS framework was used. To this end, data for the model parameters were derived from, a digital elevation model (DEM) of (30*30 m), thirty years (1988-2017) rainfall data at rain gauge stations, soil erodibility data from field soil samples, Landsat-8 satellite image for cover management and conservation support practices. Once raster layer of the input parameters created, overlay analysis was carried to assess the spatial distribution of soil loss. The estimated annual soil loss varies from 0 to 465.16 t ha−1 yr−1 with a mean annual soil loss of 9.95 t ha−1 yr−1. The empirical analysis also confirmed that the watershed losses a total of about 463365.46 t of soil annually. Out of the total area; 54.9% of the watershed was categorized below moderate classes and the remaining 45.1% of land area was classified under high to very high classes, which is about several times the maximum tolerable soil loss rate. Based on the classification of soil loss hazard map, six out of eleven Neri sub-watersheds need prior intervention in terms of integrated cover-management and mechanical conservation measures. Furthermore, model results can be refined by analyzing along with sub-watersheds level real time monitoring for conservation practices.

Abbreviations: DEM: Digital elevation model; GIS: Geographic information system; IDW: Inverse distance weighted; LULC: Land use land cover; RUSLE: Revised universal soil loss equation; TSL: Tolerable soil loss; NDVI: Normalized Difference Vegetation Index.

Angima, S. D., Stott, D. E., O"Neill, M. K., Ong C. K., & Weesies, G. A. (2003) Soil erosion prediction using RUSLE for central Kenyan highland conditions. Agriculture, Ecosystems and Environment, 97(1-3), 295-308.
Crossref
 
Bekele, B., Muluneh, A., & Wondrade, N. (2019). Geographic Information System (GIS) based soil loss estimation using Universal Soil Loss Equation Model (USLE) for soil conservation planning in Karesa Watershed, Dawuro Zone, South-west Ethiopia. International Journal of Water Resources and Environmental Engineering, 11(8), 143-158.
Crossref
 
Bai, Z., Dent, D. L., Olson, L., & Shaepman M. E. (2008) Proxy global assessment of land degradation. Soil use and Management, 24(3), 223-234.
Crossref
 
Bewket, W., & Teferi, E. (2009) Assessment of soil erosion hazard and prioritization for treatment at the watershed level: Case study in the Chemoga watershed, Blue Nile Basin, Ethiopia. Land Degradation & Development, 20(6), 609-622.
Crossref
 
Blanco, C. H., & Lal, R. (2008). Principles of soil conservation and management. Springer Science and Business Media B.V, Berlin, p. 240.
 
Bochet, E., Rubio J. L., & Poesen, J. (1998) Relative efficiency of three representative matorral species in reducing water erosion at the micro scale in a semi-arid climate, Geomorphology, 23(2-4), 139-150.
Crossref
 
Bonilla, C. A, & Johnson, O. I. (2012). Soil erodibility mapping and its correlation with soil properties in Central Chile. Geoderma, 189-190, 116-123.
Crossref
 
Brady, N. C., & Weil, R. C. (2012). The nature and properties of soils. Pearson education, New Delhi.
 
Durán, Z. V. H., Rodríguez, P. C. R., Francia, M. J. R., Cárceles R. B., Martínez R. A., & Pérez G. P. (2007). Harvest intensity of aromatic shrubs vs. soil-erosion: An equilibrium for sustainable agriculture (SE Spain), Catena, 73(1), 107-116.
Crossref
 
Fangmeier, D. D., Elliot, W. J., Workman, S. R., Huffman, R. L., & Schwab, G. O. (2006). Soil and Water Conservation Engineering. 5th ed. Thomson Delmar Learning. New York. p.35.
 
Feng, X., Wang, Y., Chen, L., Fu, B., & Bai, G. (2010). Modelling soil erosion and its response to land-use change in hilly catchments of the Chinese Loess Plateau. Geomorphology, 118(3-4), 239-248.
Crossref
 
Food and Agricultural Organization (FAO) and UNEP (1984). Provisional methodology for assessment and mapping of desertification. FAO, Rome, p.85.
 
Food and Agricultural Organization (FAO).1986. Highland reclamation study: Ethiopia. Final Report. Food and Agriculture Organization of the United Nations, Rome, Italy.
 
Foster, G. R. (1981). Conservation practices in erosion models. In: Morgan, R. P. C. (ed.). Soil Conservation: Problems and Prospects (pp. 273-278). New York: John Willy and Sons.
 
Foster, G. R., McCool, D. K., Renard, K. G., & Moldenhauer, W. C. (1981). Conversion of the universal soil loss equation to SI metric units. Journal of Soil and Water Conservation, 36(6), 355-359.
 
Brhane, G., & Mekonen, K. (2009). Estimating soil loss using Universal Soil Loss Equation (USLE) for soil conservation planning at Medego watershed, Northern Ethiopia. Journal of American Science, 5(1), 58-69.
 
Gerawork, B., & Awdenegest, M. (2014). Spatial erosion hazard assessment for proper intervention in the case of Gibe-III Dam Catchment, Southwest Ethiopia. MSc Thesis, Haramaya University.
 
Hassan, Z., Shabbir, R., Ahmad, S. S., Malik, A. H., Aziz, N., Butt, A., & Erum, S. (2016). Dynamics of land use and land cover change (LULCC) using geospatial techniques: a case study of Islamabad Pakistan. SpringerPlus, 5(1), 1-11.
Crossref
 
Hurni, H. (1985). Erosion - productivity - conservation systems in Ethiopia. Proceedings of 4th International Conference on Soil Conservation, Maracay, Venezuela. Pp. 654-674.
 
Hurni, H., Herweg, K., Portner, B., & Liniger, H. (2008). Soil erosion and conservation in global agriculture. In Land use and soil resources (pp. 41-71). Springer, Dordrecht.
Crossref
 
Hurni, H. (1990). Degradation and conservation of the resources in the Ethiopian highlands. Mountain Research and Development, 8, 123-130.
Crossref
 
Hurni, H. (1993). Land degradation, famine, and land resource scenarios in Ethiopia. World soil erosion and conservation. Pp. 27-61.
Crossref
 
Jensen, J. R. (2000). Remote sensing of the environment: An earth resource perspective prentice hall, New Jersey. Joshi VU, Nagare Land use change detection along the Pravara River Basin in Maharashtra, using Remote Sensing and GIS Techniques. AGD Landscape Environ, 3,71-86.
 
Kaltenrieder, J. (2007). Adaptation and validation of the Universal Soil Loss Equation (USLE) for the Ethiopian Eritrean Highlands. MSc Thesis, University of Berne, Centre for Development and Environment Geographisches Institute.
 
Lal, R., & Elliot, W. (1994) Erodibility and erosivity. In: Lal, R. (ed.). Soil Erosion research Methods, St. Lucie Press, Delray Beach, Florida, pp. 181-207.
Crossref
 
Mahmud, Y., Alemu, M., Menale, K., & Pender, J. (2005). Cost of land degradation in Ethiopia: A Critical Review of Past Studies. Environmental Economics Policy Forum in Ethiopia, and International Food Policy Research Institute, Addis Ababa, Ethiopia.
 
Manrique, L. A. (1988). Land erodibility assessment methodology. Manrique International Agro technology, Honolulu.
 
Mellerowicz, K. T., Rees, H. W., Chow, T. L., & Ghanem, I. (1994). Soil conservation planning at the watershed level using the Universal Soil Loss Equation with GIS and micorocomputer technologies: A case study. Journal of Soil and Water Conservation, 49(2), 194-200.
 
Mitasova, H., & Mitas, Z. (1999). Modeling soil detachment with RUSLE 3D using GIS. IL, USA: University of Illinois at Urbana -Champaign.
 
Murphy, B. W., & Flewin, T. C. (1993). Rill erosion on a structurally degraded sandy loam surface soil. Australian Journal of Soil Research, 31(4), 419-436.
Crossref
 
Pelton, J., Frazier, E., & Pickilingis, E. (2012) Calculating slope length factor (LS) in the (revised) universal soil loss equation (RUSLE) to the Ethiopian highlands.
 
Piccolo, A., Pietramellara, G., & Mbagwu, J. S. C. (1997). Use of humic substances as soil conditioners to increase aggregate stability. Geoderma, 75(3-4), 267-277.
Crossref
 
Raes, D., Willems, P., & Baguidi, F. (2006). RAINBOW - a software package for analyzing data and testing the homogeneity of historical data sets. Proceedings of the 4th International Workshop on 'Sustainable management of marginal dry lands'. Islamabad, Pakistan, 27-31 January 2006.
 
Renard, K. G., Foster, G. R., Weesies, G. A., McCool, D. K., & Yoder, D. C. (1997). Predicting soil erosion by water: A guide to conservation planning with the Revised Universal Soil Loss Equation (RUSLE). Agriculture Handbook, Vol. 703. US Department of Agriculture, US Government Printing Office, Washington DC, USA.
 
Rosewell, C. J., Crouch, R. J, Morse, R. J., Leys, J. F., Hicks, R. W., & Stanley, R. J. (2007) Forms of Erosion. In 'Soils- their properties and management'. 3rd edition. Charman, P. E. V., & Murphy, B. W. (eds.). pp. 14-40. Oxford University Press: Melbourne.
 
Rouse, J. W., Haas, R. H., Schell, J. A., & Deering, D. W. (1974). Monitoring vegetation systems in the Great Plains with ERTS. NASA special publication, 351(1974), 309-317.
 
Smith, J. L., Halvorson, J. J., & Papendick, R. I. (1993). Using multipleā€variable indicator kriging for evaluating soil quality. Soil Science Society of America Journal, 57(3), 743-749.
Crossref
 
Sonneveld, B. G. J. S. (2002). Land under pressure: The impact of water erosion on food production in Ethiopia. Shaker Publishing, Maastricht, the Netherlands.
 
Stern, R., Ben-Hur, M., & Shainberg, I. (1991). Clay mineralogy effect on rain infiltration, seal formation and soil losses. Soil Science, 152(6), 455-462.
Crossref
 
Suji, V. R., Karuppasamy, S., & Sheeja, R. V. (2015). Prioritization using morphometric analysis and land use/land cover parameters for Vazhichal watershed using remote sensing and GIS techniques. International Journal for Innovative Research in Science & Technology, 2(1), 61-68.
 
Tamene, L. (2005) Reservoir siltation in the drylands of Northern Ethiopia, Causes, Source Areas and Management Options. PhD Thesis, Center for Development Research, University Bonn, Bonn.
 
Molla, T., & Sisheber, B. (2017). Estimating soil erosion risk and evaluating erosion control measures for soil conservation planning at Koga watershed in the highlands of Ethiopia. Solid Earth, 8(1), 13-25.
Crossref
 
Vaezi, A. R., Bahrami, H. A., Sadeghi, S. H. R., & Mahdian, M. H. (2010). Spatial variability of soil erodibility factor (K) of the USLE in North West of Iran. Journal of Agricultural Science and Technology, 12(2), 241-252.
 
Wang, G., Gertner, G., Liu, X., & Anderson, A. (2001). Uncertainty assessment of soil erodibility factor for revised universal soil loss equation. Catena, 46(1), 1-14.
Crossref
 
Wischmeier, W. H., & Smith D. D. (1978). Predicting rainfall erosion losses: A guide for conservation planning. USDA Agricultural Hand book No 537, Washington, DC.
 
Woody Biomass Inventory and Strategic Planning Project (WBISPP) (2001). Southern Nations Nationalities and People's Regional State: A strategic plan for the sustainable development, conservation, and management of the woody biomass resources. Addis Ababa, Ethiopia.
 
Yang, D., Kanae, S., Oki, T., Koike, T., & Musiake, K. (2003). Global potential soil erosion with reference to land use and climate changes. Hydrological processes, 17(14), 2913-2928.
Crossref
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