Original Article
Soil and Water Assessment Tool Application in Natural Resources Management: A Systematic Review
Year: 2021 | Month: September | Volume 14 | Issue 3
1.Abbas, N., Wasimi, S.A. and Al-Ansari, N. 2017. Impacts of climate change on water resources of Greater Zab and Lesser Zab Basins, Iraq, using soil and water assessment tool model. Int. J. Environ. Chem. Ecolog. Geolog. Geophys. Eng., 11(10): 823-829.
View at Google Scholar2.Arnold, J.G., Srinivasan, R., Muttiah, R.S. and Williams, J.R. 1998. Large Area Hydrologic Modeling and Assessment Part I: Model Development. J. Am. Water Resour. Assoc., 34: 73-89.
View at Google Scholar3.Ayana, A.B., Edossa, D.C. and Kositsakulchai, E. 2012. Simulation of sediment yield using SWAT model in Fincha Watershed, Ethiopia. Agric. Nat. Resour., 46(2): 283-297.
View at Google Scholar4.Briak, H., Moussadek, R., Aboumaria, K. and Mrabet, R. 2016. Assessing sediment yield in Kalaya gauged watershed (Northern Morocco) using GIS and SWAT model. Int. Soil Water Conserv. Res., 4(3): 177-185.
View at Google Scholar5.Chanapathi, T., Thatikonda, S., Keesara, V.R. and Ponguru, N.S. 2020. Assessment of water resources and crop yield under future climate scenarios: A case study in a Warangal district of Telangana, India. J. Earth Syst. Sci., 129(1): 1-17.
View at Google Scholar6.Dibaba, W.T., Demissie, T.A. and Miegel, K. 2021. Prioritization of Sub-Watersheds to Sediment Yield and Evaluation of Best Management Practices in Highland Ethiopia, Finchaa Catchment. Land, 10(6): 650.
View at Google Scholar7.Djebou, D.C.S. 2018. Assessment of sediment inflow to a reservoir using the SWAT model under undammed conditions: A case study for the Somerville reservoir, Texas, USA. Int. Soil Water Conserv. Res., 6(3): 222-229.
View at Google Scholar8.Douglas-Mankin, K.R., Srinivasan, R. and Arnold, J.G. 2010. Soil and Water Assessment Tool (SWAT) model: Current developments and applications. Trans ASABE, 53: 1423-1431.
View at Google Scholar9.Githui, F., Mutua, F. and Bauwens, W. 2009. Estimating the impacts of land-cover change on runoff using the soil and water assessment tool (SWAT): case study of Nzoia catchment, Kenya. Hydrol Sci. J., 54(5): 899-908.
View at Google Scholar10.Hajihosseini, M., Hajihosseini, H., Morid, S., Delavar, M. and Booij, M.J. 2020. Impacts of land use changes and climate variability on transboundary Hirmand River using SWAT. J. Water Clim. Change, 11(4): 1695-1711.
View at Google Scholar11.Hyandye, C.B., Worqul, A., Martz, L.W. and Muzuka, A.N. 2018. The impact of future climate and land use/cover change on water resources in the Ndembera watershed and their mitigation and adaptation strategies. Environ. Syst. Res., 7(1): 1-24.
View at Google Scholar12.Jiang, R.G., Xie, J.C., Zhao, Y., He, H.L. and He, G.H. 2017. Spatiotemporal variability of extreme precipitation in Shaanxi Province under climate change. Theor. Appl. Climatol., 130(3-4): 831-845.
View at Google Scholar13.Kavian, A., Mohammadi, M., Gholami, L. and Rodrigo- Comino, J. 2018. Assessment of the spatiotemporal effects of land use changes on runoff and nitrate loads in the Talar River. Water, 10(4): 445.
View at Google Scholar14.Krause, P., Boyle, D.P. and Base, F. 2005. Comparison of different efficiency criteria for hydrological model assessment. Adv. Geosci., 5: 89–97.
View at Google Scholar15.Kumar, S., Raghuwanshi, N.S. and Mishra, A. 2015 Identification and management of critical erosion watersheds for improving reservoir life using hydrological modeling. Sustain. Water Resour. Manag., 1: 57–70.
View at Google Scholar16.Mamo, K.H.M. and Jain, M.K. 2013. Runoff and sediment modeling using SWAT in Gumera catchment, Ethiopia. Open Journal of Modern Hydrology, 2013.
View at Google Scholar17.Pandey, Ashish, Bishal K.C., Kalura P., Chowdary V.M., Jha, C.S. and Artemi, C. 2021 A Soil Water Assessment Tool (SWAT) Modeling Approach to Prioritize Soil Conservation Management in River Basin Critical Areas Coupled with Future Climate Scenario Analysis. Air Soil Water Res., 14.
View at Google Scholar18.Patel, D.P. and Nandhakumar, N. 2016. Runoff potential estimation of Anjana Khadi Watershed using SWAT model in the part of lower Tapi Basin, West India. Sustain. Water Resour. Manag., 2(1): 103-118.
View at Google Scholar19.Puno, R.C.C., Puno, G.R. and Talisay, B.A.M. 2019. Hydrologic responses of watershed assessment to land cover and climate change using soil and water assessment tool model. Glob. J. Environ. Sci. Manag., 5(1): 71-82.
View at Google Scholar20.Rakshit, A., Abhilash, P.C., Singh, H.B. and Ghosh, S. 2017. Adaptive Soil Management: From Theory to Practices, 571p, Springer-Verlag Singapore. ISBN: 978-9811036378.
View at Google Scholar21.Santra, P. and Das, B.S. 2013. Modeling runoff from an agricultural watershed of western catchment of Chilika lake through ArcSWAT. J. Hydro-Environ. Res., 7(4): 261- 269.
View at Google Scholar22.Shawul, A.A., Alamirew, T. and Dinka, M.O. 2013. Calibration and validation of SWAT model and estimation of water balance components of Shaya mountainous watershed, Southeastern Ethiopia. Hydrol. Earth Syst. Sci., 10(11): 13955-13978.
View at Google Scholar23.Singh, A., Imtiyaz, M., Isaac, R.K. and Denis, D.M. 2014. Assessing the performance and uncertainty analysis of the SWAT and RBNN models for simulation of sediment yield in the Nagwa watershed, India. Hydrol Sci. J., 59(2): 351-364.
View at Google Scholar24.Singh, B. and Saika, B.P. 1990. Water table control through pipe drains in tea soils, in: Tea Research Global Perspective, Proc. Int. Conf. Res. Dev. Tea, 74.
View at Google Scholar25.Singh, R.K. 2002. Soil conservation measures in agricultural land. In Integrated Watershed Management for Sustainable Development, (ICAR Research complex for NEH region, Umiam, Meghalaya), 104.
View at Google Scholar26.Tang, F.F., Xu, H.S. and Xu, Z.X. 2012. Model calibration and uncertainty analysis for runoff in the Chao River Basin using sequential uncertainty fitting. Procedia Environ. Sci., 13: 1760-1770.
View at Google Scholar27.Villamizar, S.R., Pineda, S.M. and Carrillo, G.A. 2019. The effects of land use and climate change on the water yield of a watershed in Colombia. Water, 11(2): 285.
View at Google Scholar28.Wang, Y., Jiang, R., Xie, J., Zhao, Y., Yan, D. and Yang, S. 2019. Soil and water assessment tool (SWAT) model: A systemic review. J. Coast. Res., 93(SI): 22-30.
View at Google Scholar29.Welde, K. and Gebremariam, B. 2017. Effect of land use land cover dynamics on hydrological response of watershed: Case study of Tekeze Dam watershed, northern Ethiopia. Int. Soil Water Conserv. Res., 5(1): 1-16.
View at Google Scholar30.Welde, K. 2016. Identification and prioritization of subwatersheds for land and water management in Tekeze dam watershed, Northern Ethiopia. Int. Soil Water Conserv. Res., 4(1): 30-38.
View at Google Scholar31.Zhang, L., Meng, X., Wang, H. and Yang, M. 2019. Simulated runoff and sediment yield responses to land-use change using the SWAT model in northeast China. Water, 11(5): 915.
View at Google Scholar