Soil & Water Res., 2020, 15(1):18-29 | DOI: 10.17221/202/2018-SWR

Using WaTEM/SEDEM and HEC-HMS models for the simulation of episodic hydrological and erosion events in a small agricultural catchmentOriginal Paper

Jana Konečná*,1, Petr Karásek1, Hana Beitlerová1, Petr Fučík1, Jiří Kapička1, Jana Podhrázská1, Tomáš Kvítek2
1 Research Institute for Soil and Water Conservation, Prague, Czech Republic
2 University of South Bohemia in České Budějovice, České Budějovice, Czech Republic

A careful analysis of rainfall-runoff events and patterns of sediment and pollution load to water bodies is crucial for the proper management of agricultural land. This study simultaneously employed the WaTEM/SEDEM long-term erosion model and the HEC-HMS episodic hydrological and erosion model to describe the runoff and sediment load evoked by extreme rainfall events in a small agricultural catchment in Czechia, using the long-term monitoring discharge and water quality episodic data. WaTEM/SEDEM helped to delineate the runoff and sediment critical source areas, subsequently incorporated into HEC-HMS. The acquired results showed that the spatial distribution of land use is a fundamental factor in the protection of watercourses from diffuse pollution sources and the transport and delivery of sediment profoundly depends on the status of crop cover on arable land near a watercourse. Integrating both models, it was shown that the tabulated Curve Number (CN) values as well as the average C-factor values had to be lowered for the majority of the modelled events to match the monitored data. A noticeable role of catchment runoff response most probably played tile drainage, which appeared to profoundly modify the episodic runoff pattern. This study showed a promising approach for the simulation of different rainfall-runoff responses of small agricultural catchments and could be applied for the delineation of areas where soil conservation measures or protective management is of high priority. The results further revealed the obvious need to revise the CN values for tile-drained catchments.

Keywords: CN method; modelling; runoff; sediment transport; soil erosion

Published: March 31, 2020  Show citation

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Konečná J, Karásek P, Beitlerová H, Fučík P, Kapička J, Podhrázská J, Kvítek T. Using WaTEM/SEDEM and HEC-HMS models for the simulation of episodic hydrological and erosion events in a small agricultural catchment. Soil & Water Res. 2020;15(1):18-29. doi: 10.17221/202/2018-SWR.
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    References

    1. Bača P. (2008): Hysteresis effect in suspended sediment concentration in the Rybárik Basin, Slovakia. Hydrological Sciences Journal, 53: 224-235. Go to original source...
    2. Bishop P.L., Hively W.D., Stedinger J.R., Rafferty M.R., Lojpersberger J.L., Bloomfield J.A. (2004): Multivariate analysis of paired catchment data to evaluate agricultural best management practice effects on stream water phosphorus. Journal of Environmental Quality, 34: 1087-1101. Go to original source... Go to PubMed...
    3. Dostál T., Janeček M., Kliment Z., Krása J., Langhammer J., Váška J., Vrána K. (2006): Czech Republic. In: Boardman J., Poesen J. (eds.): Soil Erosion in Europe. Chichester, J. Wiley & Sons: 107-116. Go to original source...
    4. Fučík P., Hejduk T., Peterková J. (2015): Quantifying water pollution sources in a small tile-drained agricultural watershed. CLEAN - Soil Air Water, 43: 698-709. Go to original source...
    5. Janeček M. (1981): Facility for taking samples during higher outflows in drainage outfalls. Vodní Hospodářství, A31: 55. (in Czech)
    6. Janeček M. et al. (2012): Protection of Agricultural Land against Erosion. Methodology. Prague, Powerprint, s.r.o. (in Czech)
    7. Janeček M., Květoň V., Kubátová E., Kobzová D., Vošmerová M., Chlupsová J. (2013): Values of rainfall erosivity factor for the Czech Republic. Journal of Hydrology and Hydromechanics, 61: 97-102. Go to original source...
    8. Janků J., Sekáč P., Baránková J., Kozák J. (2016): Land use analysis in terms of farmland protection in the Czech Republic. Soil and Water Research, 1: 20-28. Go to original source...
    9. Karásek P., Podhrázská J., Kučera J., Konečná J., Pochop M. (2018): Priority areas for initiating land consolidations related to erosion and water retention in the landscape, the Czech Republic. Journal of Ecological Engineering, 19: 16-28. Go to original source...
    10. King K.W., Fausey N.R., Williams M.R. (2014): Effect of subsurface drainage on streamflow in an agricultural headwater watershed. Journal of Hydrology, 519: 438-445. Go to original source...
    11. Konečná J., Karásek P., Fučík P., Podhrázská J., Pochop M., Ryšavý S., Hanák R. (2017): Integration of soil and water conservation measures in an intensively cultivated catchment - a case study of Jihlava river basin. European Countryside, 1: 17-28. Go to original source...
    12. Krása J., Dostál T., Rosendorf P., Borovec J., Hejzlar J. (2015): Modelling of sediment and phosphorus loads in reservoirs in the CR. In: Fullen M.A., Famodimu J., Karyotis T., Noulas C., Panagopoulos A., Rubio J.L., Gabriels D. (eds.): Innovative Strategies and Policies for Soil Conservation. Reiskirchen, Catena Verlag: 21-34.
    13. Krasa J., Dostal T., Jachymova B., Bauer M., Devaty J. (2019): Soil erosion as a source of sediment and phosphorus in rivers and reservoirs - Watershed analyses using WaTEM/SEDEM. Environmental Research, 171: 470-483. Go to original source... Go to PubMed...
    14. Kronvang B., Larsen S., Jensen J., Andersen H., Hejzlar J. (2005): Catchment Report: Zelivka, Czech Republic - trend analysis, retention and source apportionment. In: EUROHARP Report 17-2005. Oslo, Norwegian Institute for Water Research.
    15. Kvítek T. et al. (2017) Water Retention and Quality in Catchment of the Drinking Water Reservoir Švihov on the Želivka River. Praha, Povodí Vltavy s.p. (in Czech)
    16. Laudon H., Sponseller R.A. (2018): How landscape organization and scale shape catchment hydrology and biogeochemistry: insights from a long-term catchment study. WIREs Water, 5: e1265. Go to original source...
    17. Lefrancq M., Van Dijk P., Jetten V., Schwob M., Payraupeau S. (2017): Improving runoff prediction using agronomical information in a cropped, loess covered catchment. Hydrological Processes, 31: 1408-1423. Go to original source...
    18. Lieskovský J., Kenderessy P. (2014): Modelling the effect of vegetation cover and different tillage practices on soil erosion in vineyards: a case study in Vráble (Slovakia) using WaTEM/SEDEM. Land Degradation & Development, 25: 288-296. Go to original source...
    19. Moriasi D.N., Arnold J.G., Van Liew M.W., Binger R.L., Harmel R.D., Veith T.L. (2007): Model evaluation guidelines for systematic quantification of accuracy in catchment simulations. American Society of Agricultural and Biological Engineers, 50: 885-900. Go to original source...
    20. Nagle G.N., Ritchie J.C. (2004): Wheat field erosion rates and channel bottom sediment sources in an intensively cropped northeastern Oregon drainage basin. Land Degradation and Development, 15: 15-26. Go to original source...
    21. Noori N., Kalin L., Srivastava P., Lebleu C. (2012): Effects of initial abstraction ratio in SCS-CN method on modeling the impacts of urbanization on peak flows. In: Loucks E.D. (ed.): World Environmental and Water Resources Congress 2012: Crossing Boundaries, Albuquerque, May 20-24, 2012: 329-338. Go to original source...
    22. Pak J.H., Fleming M., Scharffenberg W., Gibson S., Brauer T. (2015): Modelling surface soil erosion and sediment transport processes in the Upper North Bosque River Catchment, Texas. Journal of Hydrologic Engineering, 20: 1-13. Go to original source...
    23. Pavlík F., Dumbrovský M., Podhrázská J., Konečná J. (2012): The influence of water erosion processes on sediment and nutrient transport from a small agricultural catchment area. Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis, 60: 155-164. Go to original source...
    24. Renard K.G., Foster G.R., Weesies G.A., McCool D.K., Yoder D.C. (2000): Predicting Soil Erosion by Water: a Guide to Conservation Planning with the Revised Universal Soil Loss Equation (RUSLE). Agriculture Handbook No 703. Washington, USDA.
    25. Singh J., Knapp H.V., Arnold J.G., Demissie M. (2005): Hydrologic modelling of the Iroquois river catchment using HSPF and SWAT. Journal of the American Water Resources Association, 41: 361-375. Go to original source...
    26. Svoboda V., Hanel M., Máca P., Kyselý J. (2016): Projected changes of rainfall event characteristics for the Czech Republic. Journal of Hydrology and Hydromechanics, 64: 415-425. Go to original source...
    27. USACE (2013): Hydrologic Modeling System HEC-HMS: User's Manual. Davis, Hydrologic Engineering Center.
    28. Uhlířová J., Kaplická M., Kvítek T. (2009): Water erosion and characteristics of sediment load in the Kopaninský stream basin. Soil and Water Research, 4: 39-46. Go to original source...
    29. Van Rompaey A., Verstraeten G., Van Oost K., Govers G., Poesen J. (2006): Modelling mean annual sediment yield using a distributed approach. Earth Surface Processes and Landforms, 26: 1221-1236. Go to original source...
    30. Van Rompaey A., Krasa J., Dostal T. (2007): Modelling the impact of land cover changes in the Czech Republic on sediment delivery. Land Use Policy, 24: 576-583. Go to original source...
    31. Verma S., Verma R.K., Mishra S.K., Singh A., Jayaraj G.K. (2017): A revisit of NRCS-CN inspired models coupled with RS and GIS for runoff estimation. Hydrological Sciences Journal, 62: 1891-1930. Go to original source...
    32. Vopravil J., Janeček M., Tippl M. (2007): Revised soil erodibility K-factor for soils in the Czech Republic. Soil and Water Research, 2: 1-9. Go to original source...
    33. Walling D.E. (2009): The Impact of Global Change on Erosion and Sediment Transport by Rivers: Current Progress and Future Challenges. Paris, UNESCO.
    34. WaTEM/SEDEM (2006): Available at http://geo.kuleuven.be/geography/modelling/erosion/watemsedem/index.htm (Accessed Nov 2017).
    35. Zabaleta A., Martínez M., Uriarte J.A., Antiguedad I. (2007): Factors controlling suspended sediment yield during runoff events in small headwater catchments of the Basque Country. Catena, 71: 179-190. Go to original source...
    36. Žížala D., Zádorová T., Kapička J. (2017): Assessment of soil degradation by erosion based on analysis of soil properties using aerial hyperspectral images and ancillary data, Czech Republic. Remote Sensing, 9: 28. Go to original source...
    37. Žlábek P., Kaplická M., Kulhavý Z. (2002): Comparison between simulations of significant rainfall-runoff events generated by SCS-CN-based model and measured data in three subcatchments with different land use. Littera Scripta, 5: 275-284.

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