Quantification of Soil Erosion by Integrating Geospatial and Revised Universal Soil Loss Equation in District Dir Lower, Pakistan

Soil Erosion Estimation using RUSLE Model

Authors

  • Abdullah Khan Department of Geography, University of Peshawar, Peshawar, Pakistan
  • Atta-ur-Rahman Department of Geography, University of Peshawar, Peshawar, Pakistan

DOI:

https://doi.org/10.53560/PPASB(58-4)678

Keywords:

Soil Erosion, RUSLE, Deforestation, GIS, Lower Dir

Abstract

This study is aimed to estimate soil erosion risk by integrating Revised Universal Soil Loss Equation (RUSLE) and geospatial tool in District Lower Dir, Eastern Hindu Kush. Soil erosion is among the biggest threats to agricultural production. Mountainous areas of Pakistan are exposed to erosion hazards due to immature geology, fragile slope, and deforestation. RUSLE factors were derived from data acquired from various sources. The Rainfall erosivity (R) factor was derived from monthly data obtained from Pakistan Meteorological Department, Peshawar. The soil erodibility (K) factor was prepared from the map of soil, Survey of Pakistan. The topography (LS) factor was calculated from 12.5 m DEM downloaded from the Alaska Satellite Facility. The cover management (C) factor was calculated from the Red and Near-Infrared band of Landsat 8 satellite image downloaded from USGS earth explorer. The Digital Elevation Model (DEM) and Landsat image were integrated to prepare the Support practice (P) factor. These factors were combined to assess soil erosion in the study area. The estimated soil erosion ranges between 0-25407 tons/hectare/year, with a mean soil loss of 230 tons/hectare/year. The erosion zonation map was then prepared and was classified as very low, low, moderate, high, and very high erosion. 22 % of the district was affected by low to moderate erosion while 67 % area is affected by very high erosion. The areas having more rainfall and steep slopes are more exposed to erosion hazards. Therefore, Erosion control activities are essential in those areas where erosion is high to assure a viable ecosystem.

References

Y. Mesfin, and S. Taddese. Assessment of a case study of Wombeya watershed, Awash basin, Ethiopia. International Journal of Current Research 11(7): 573-5738 (2019).

D.P. Finlayson, and D.R. Montgomery. Modelling large-scale fluvial erosion in geographic information systems. Geomorphology 53(1-2): 147-164 (2003).

I. Bayramin, O. Dengiz, O. Baskan, and M. Parlak. Soil erosion risk assessment with ICONA model; case study: Beypazarı area. Turkish Journal of Agriculture and Forestry 27(2): 105-116 (2003).

P. Borrelli, D.A. Robinson, P. Panagos, E. Lugato, J.E. Yang, C. Alewell, D. Wuepper, L. Montanarella, and C. Ballabio. Land use and climate change impacts on global soil erosion by water (2015- 2070). Proceeding of the National Academy of Sciences 117(36): 21994–22001 (2020).

L. Tamene, and P.L.G. Vlek. Soil erosion studies in northern Ethiopia. In: Land use and soil resources. A.K. Braimoh, & P.L.G. Vlek (Ed.), Springer, Dordrecht, p. 73-100 (2008).

I.O. Utuk, and E.E. Daniel. Land degradation: a threat to food security: a global assessment. Journal of Environment and Earth Science 5(8): 13- 21(2015).

FAO. A healthy soil is a living soil (2015). http:// www.fao. org/ soils2015 / news/ news-detail/ en/c/281917/ (accessed 27 September 2021).

D. Pimentel, and M. Burgess. Soil Erosion Threatens Food Production. Agriculture 3(3): 443-463 (2013).

D. Pimentel, C. Harvey, P. Resosudarmo, K. Sinclair, D. Kurz, M. McNair, S. Crist, L. Shpritz, L. Fitton, R. Saffouri, and R. Blair. Environmental and Economic Costs of Soil Erosion and Conservation Benefits. Science 267(5201): 1117-1123 (1995).

C. Jie, C. Jing-zhang, T. Man-zhi, and G. Zi-tong. Soil degradation: a global problem endangering sustainable development. Journal of Geographical Sciences 12(2): 243-252 (2002).

V. Vanacker, G. Govers, S. Barros, J. Poesen, and J. Deckers. The effect of short-term socio-economic and demographic change on land use dynamics and its corresponding geomorphic response with relation to water erosion in a tropical mountainous catchment, Ecuador. Landscape Ecology 18(1): 1-15 (2003).

S. Pandey, P. Kumar, M. Zlatic, R. Nautiyal, V.P. Panwar. Recent advances in assessment of soil erosion vulnerability in a watershed. International Soil and Water Conservation Research 9(3): 305- 318 (2021).

Y.S. Kebede, B.G. Sinshaw, N.T. Endalamaw, H.B. Atinkut. Modeling soil erosion using RUSLE and GIS at watershed level in the upper beles, Ethiopia. Environmental Challenges, 2: 1-9 (2020).

Y. Farhan, D. Zregat, and I. Farhan. Spatial estimation of soil erosion risk using RUSLE approach, RS, and GIS techniques: a case study of Kufranja watershed, Northern Jordan. Journal of Water Resource and Protection 5(12): 1247 (2013).

S. Khan, and M. Hasan. Climate Change Impacts and Adaptation to Flow of Swat River and Glaciers in Hindu Kush Ranges, Swat District, Pakistan (2003-2013). International Journal of Economic and Environmental Geology 7(1): 24-35 (2016).

S. Dutta. Soil erosion, sediment yield and sedimentation of reservoir: a review. Modelling Earth Systems and Environment 2(3): 1-18 (2016).

O.C.A. Erenstein. The economics of soil conservation in developing countries: The case of crop residue mulching. Doctoral Dissertation, Wageningen University and Research Netherlands 315 pp. (1999).

G. Ashiagbor, E.K. Forkuo, P. Laari, and R. Aabeyir. Modeling soil erosion using RUSLE and GIS tools. International Journal of Remote Sensing and Geoscience 2(4): 1-17 (2013).

M.A. Khan, M. Ahmad, and H.S. Hashmi. Review of Available Knowledge on Land Degradation in Pakistan. OASIS Country Report, (ICARDA) 3:1-22 (2012).

M. Irshad, M. Inoue, M., Ashraf, Faridullah, H.K.M. Delower, and A. Tsunekawa. Land Desertification- An Emerging Threat to Environment and Food Security of Pakistan. Journal of Applied Sciences 7(8): 1199-1205 (2007).

S.D. Keesstra, J. Bouma, J. Wallinga, P. Tittonell, P. Smith, A. Cerdà, L. Montanarella, J.N. Quinton, Y. Pachepsky, W.H. Van Der Putten, R.D. Bardgett, S. Moolenaar, G. Mol, B. Jansen, and L.O. Fresco. The significance of soils and soil science towards realization of the United Nations Sustainable Development Goals. Soil 2(2): 111-128 (2016).

S. Keesstra, G. Mol, J. De Leeuw, J. Okx, M. De Cleen, and S. Visser. Soil-related sustainable development goals: Four concepts to make land degradation neutrality and restoration work. Land 7(4): 1-20 (2018).

R. Wang, S. Zhang, J. Yang, L. Pu, C. Yang, L. Yu, L. Change, and K. Bu. Integrated use of GCM, RS, and GIS for the assessment of hillslope and gully erosion in the Mushi River Sub-Catchment, Northeast China. Sustainability 8(4): 317 (2016).

A. Röder, J. Hill, T. Kuemmerle, G. del Barrio, V.P. Papanastasis, and G.M. Tsiourlis. Geomatics- based characterization of spatial and temporal trends in heterogeneous Mediterranean rangelands of Northern Greece. In: Recent Advances in Remote Sensing and Geoinformation Processing for Land Degradation Assessment. A. Röder, & J. Hill (Ed.), CRC Press, p. 301-320 (2009).

A. Aiello, M. Adamo, and F. Canora. Remote sensing and GIS to assess soil erosion with RUSLE3D and USPED at river basin scale in southern Italy. Catena 131: 174-185 (2015).

H.J. Smith. Application of empirical soil loss models in southern Africa: A review. South African Journal of Plant and Soil 16(3): 158-163 (1999).

V. Prasannakumar, H. Vijith, S. Abinod, and N.J.G.F. Geetha. Estimation of soil erosion risk within a small mountainous sub-watershed in Kerala, India, using Revised Universal Soil Loss Equation (RUSLE) and geo-information technology. Geoscience frontiers 3(2): 209-215 (2012).

L.C. Kulimushi, P. Choudhari, A. Maniragaba, A. Elbeltagi, M. Mugabowindekwe, G. Rwanyiziri, R.V. Byizigiro, S.M. Pingale, and S.K. Singh. Erosion risk assessment through prioritization of sub-watersheds in Nyabarongo river catchment, Rwanda. Environmental Challenges 5: 1-20 (2021).

D.L. Karlen, and C.W. Rice. Soil degradation: Will humankind ever learn? Sustainability 7(9): 12490- 12501 (2015).

M.A.G. Fujaco, M.G.P. Leite, and A.H.C.J. Neves. A GIS-based tool for estimating soil loss in agricultural river basins. REM-International Engineering Journal 69(4): 417-424 (2016).

E.P.N. Udayakumara, R.P. Shrestha, L. Samarakoon, and D. Schmidt-Vogt. People’s perception and socioeconomic determinants of soil erosion: A case study of Samanalawewa watershed, Sri Lanka. International Journal of Sediment Research 25(4): 323-339 (2010).

W. S. Merritt, R.A. Letcher, and A.J.A. Jakeman. A review of erosion and sediment transport models. Environmental Modelling and Software 18(8-9): 761-799 (2003).

GoP. Provisional summary results of 6th population and housing census-2017. Population Census Organization, Statistics Division. Govt. of Pakistan. (2017).

E.H. Cobb. The frontier states of Dir, Swat and Chitral. Journal of the Royal Central Asian Society 38(2-3): 170-176 (1951).

K.G. Renard, G.R. Foster, D.C. Yoder, and D.K. McCool. RUSLE revisited: status, questions, answers, and the future. Journal of soil and water conservation 49(3): 213-220 (1994).

K.G. Renard, and V.A. Ferreira. RUSLE model description and database sensitivity. Journal of environmental quality 22(3): 458 (1993).

G.R. Foster, D.C. Yoder, G.A. Weesies, D.K. McCool, K.C. McGregor, and R.L. Bingner. Users Guide: revised universal soil loss equation. USDA- Agricultural Research Service, Washington, DC, 76 (2003).

K.G. Renard, G.R. Foster, G.A. Weesies, D.K. McCool, D.C. Yoder. Predicting Soil Erosion by Water: A Guide to Conservation Planning with the Revised Universal Soil Loss Equation. USDA Agricultural Handbook No 703. U.S. Govt. Print. Office, Washington, D.C (1997).

J.H. Lee, and J.H. Heo. Evaluation of estimation methods for rainfall erosivity based on annual precipitation in Korea. Journal of Hydrology 409(1- 2): 30-48 (2011).

S.H. Teh. Soil erosion modelling using RUSLE and GIS on Cameron highlands, Malaysia for hydropower development. Master thesis, The School for Renewable Energy Science Solborg, 74 pp. (2011).

G. Singh, S. Chandra, and R. Babu. (1981). Soil loss and prediction research in India, Central Soil and Water Conservation Research Training Institute. Bulletin No T-12 D, 9 (1981).

P. Bols. The Iso-erodent Map of Java and Madura. Belgian Technical Assistance Project ATA 105, Soil Research Institute, Bogor (1978).

R. Babu, S.K. Gupta, K.G. Tejwani, and N.S. Rawat. Correlation of daily, monthly and annual rainfall with energy intensity product. In Read at VII annual meeting of ISAE, Pantnagar (1969).

J. Thomas, S. Joseph, and K.P. Thrivikramji. Assessment of soil erosion in a tropical mountain river basin of the southern Western Ghats, India using RUSLE and GIS. Geoscience Frontiers 9(3): 893-906 (2018).

G.E.Yufeng, J.A. Thomasson, and R. Sui. Remote sensing of soil properties in precision agriculture: A review. Frontiers of Earth Science 5(3): 229-238 (2011).

G.O. Schwab, R.K. Frevert, T.W. Edminster, and K.K. Barnes. Soil and water conservation engineering. John Wiley and Sons (1981).

B.A. Stewart, D.A. Woolhiser, W.H. Wischmeier, J.H. Caro, and M.H. Frere. Control of water pollution from cropland. Vol. I and II. US Department of Agriculture and Environmental Protection Agency, Washington, DC (1975).

T. Gashaw, T. Tulu, and M. Argawal. Erosion risk assessment for prioritization of conservation measures in Geleda watershed, Blue Nile basin, Ethiopia. Environmental Systems Research 6 (1): 1-16 (2017).

W.H. Wischmeier, and D.D. Smith. Predicting rainfall erosion losses-a guide to conservation planning. Agriculture Handbook No. 537. U.S. Department of Agriculture, Science and Education Administration (1978).

G.W. Haile, and M. Fetene. Assessment of soil erosion hazard in Kilie catchment, East Shoa, Ethiopia. Land Degradation and Development 23(3): 293-306 (2012).

R.D. Van Remortel, M.E. Hamilton, and R.J. Hickey. Estimating the LS factor for RUSLE through iterative slope length processing of digital elevation data within Arclnfo grid. Cartography 30(1): 27-35. (2001).

P. Panagos, P. Borrelli, and K. Meusburger. A new European slope length and steepness factor (LS-Factor) for modeling soil erosion by water. Geosciences 5(2): 117-126 (2015).

A. Bizuwerk, G. Taddese, and Y. Getahun. (2008). Application of GIS for modeling soil loss rate in Awash Basin, Ethiopia. International Livestock Research Institute (ILRI) (2008).

J. Biesemans, M. Van Meirvenne, and D. Gabriels. Extending the RUSLE with the Monte Carlo error propagation technique to predict long-term average off-site sediment accumulation. Journal of Soil and Water Conservation 55(1): 35-42 (2000).

R.J. Patil, and S.K. Sharma. Remote Sensing and GIS based modeling of crop/cover management factor (C) of USLE in Shakker river watershed. In International conference on chemical, agricultural and medical sciences (CAMS-2013), p. 29-30 (2013).

A. Karaburun. Estimation of C factor for soil erosion modelling using NDVI in Buyukcekmece watershed. Ozean Journal of Applied Sciences 3(1): 77-85 (2010).

A.M. Rojas-González. Soil erosion calculation using remote sensing and GIS in RÍO grande de Arecibo Watershed, Puerto Rico. Proceedings ASPRS 2008 Annual Conference Bridging the Horizons: New Frontiers in Geospatial Collaboration, Portland, Oregon (2008).

A. Kumar, M. Devi, and B. Deshmukh. Integrated remote sensing and geographic information system based RUSLE modelling for estimation of soil loss in western Himalaya, India. Water resources management 28(10): 3307-3317 (2014).

J.M. Van der Knijff, R.J.A. Jones, and L. Montanarella. Soil erosion risk: assessment in Europe. Scientific-Technical Reports, European commission directorate joint research centre (2000).

V.L. Durigon, D.F. Carvalho, M.A.H. Antunes, P.T.S. Oliveira, and M.M. Fernandes. NDVI time series for monitoring RUSLE cover management factor in a tropical watershed. International Journal of Remote Sensing 35(2): 441-453 (2014).

T.J. Toy, G.R. Foster, and K.G. Renard. RUSLE for mining, construction and reclamation lands. Journal of Soil and Water Conservation 54(2): 462-467 (1999).

K.G. Renard, D.C. Yoder, D.T. Lightle, and S.M. Dabney. Universal soil loss equation and revised universal soil loss equation. In: Handbook of erosion modelling. R.P.C. Morgan, & M.A. Nearing (Ed.), Chichester: Blackwell Publishing Ltd, p. 137-167 (2011).

K.G. Renard, and G.R. Foster. Soil conservation: principles of erosion by water. Dry land agriculture 23: 155-176 (1983).

C.G. Wener. Soil Conservation in Kenya especially in small-scale farming in high potential areas using labour intensive methods (6th Ed.). Ministry of Agriculture, Soil Conservation Extension Unit (1980).

G.J. Shin. The analysis of soil erosion analysis in watershed using GIS. Doctoral Dissertation, Department of Civil Engineering, Gang-won National University, South Korea 131 p. (1999).

R.P. Stone, and D. Hilborn. Universal Soil Loss Equation (USLE). Ministry of Agriculture, Food and Rural Affairs, Ontario (2012).

Downloads

Published

2021-12-12

How to Cite

Khan, A. ., & Atta-ur-Rahman. (2021). Quantification of Soil Erosion by Integrating Geospatial and Revised Universal Soil Loss Equation in District Dir Lower, Pakistan: Soil Erosion Estimation using RUSLE Model. Proceedings of the Pakistan Academy of Sciences: B. Life and Environmental Sciences, 58(4), 17–28. https://doi.org/10.53560/PPASB(58-4)678

Issue

Vol. 58 No. 4 (2021)

Section

Research Articles

License

Creative Commons Attribution (CC BY). Allows users to: copy the article and distribute; abstracts, create extracts, and other revised versions, adaptations or derivative works of or from an article (such as a translation); include in a collective work (such as an anthology); and text or data mine the article. These uses are permitted even for commercial purposes, provided the user: includes a link to the license; indicates if changes were made; gives appropriate credit to the author(s) (with a link to the formal publication through the relevant DOI); and does not represent the author(s) as endorsing the adaptation of the article or modify the article in such a way as to damage the authors' honor or reputation.