Factors controlling sediment yield at the catchment scale in NW Mediterranean geoecosystems

de Vente, J.; Verduyn, R.; Verstraeten, G.; Vanmaercke, Matthias; Poesen, J.

doi:10.1007/s11368-011-0346-3

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Factors controlling sediment yield at the catchment scale in NW Mediterranean geoecosystems

de Vente, J.; Verduyn, R.; Verstraeten, G. et al.

2011 • In Journal of Soils and Sediments, 11 (4), p. 690-707

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https://hdl.handle.net/2268/208663

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10.1007/s11368-011-0346-3

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Keywords :

ART model; Mediterranean; Multiple regression; Prediction; Sediment yield; Soil erosion; Spanish reservoirs; Mediterranean environment

Abstract :

[en] Purpose: This study aimed to (1) increase understanding of the relation between sediment yield and environmental variables at the catchment scale; (2) test and validate existing and newly developed regression equations for prediction of sediment yield; and (3) identify how better predictions may be obtained. Materials and methods: A correlation and regression analysis was performed between sediment yield and over 40 environmental variables for 61 Spanish catchments. Variables were selected based on availability and expected relation with diverse soil erosion and sediment transport processes. For comparison, the Area Relief Temperature (ART) sediment delivery model was applied to the same catchments. Sediment yield estimates obtained from reservoir surveys were used for model calibration and validation. Results and discussion: Catchment area, catchment perimeter, stream length, relief ratio, Modified Fournier Index, the RUSLE's R factor, and catchments percentage with poor vegetation cover showed highest correlations with sediment yield. Stepwise linear regression revealed that variables representing topography, climate, vegetation, lithology, and soil characteristics are required for the best prediction equation. Although calibration results were relatively good, validation showed that the models were unstable and not suitable for extrapolation to other catchments. Reasons for this unstable model performance include (1) lack of detail and quality of the data sources; (2) large variation in catchment characteristics; (3) insufficient representation of all relevant erosion and sediment transport processes; and (4) the presence of nonlinear relations between sediment yield and environmental variables. The nonlinear ART model performed relatively well but systematically overpredicted sediment yield. A model reflecting human impacts, including dams and conservation measures, is expected to provide better results. This, however, requires significantly more input data. Conclusions: Although important insight is obtained into the relation between sediment yield and environmental factors, prediction of sediment yield at the catchment scale requires alternative approaches. More detailed information is required on land cover (change), and the effect of soil conservation measures. Validation of regression equations is a necessity, and better predictions are obtained by nonlinear models. © 2011 Springer-Verlag.

Disciplines :

Earth sciences & physical geography

Author, co-author :

de Vente, J.; Estación Experimental de Zonas Áridas, EEZA-CSIC, Department of Desertification and Geoecology, Carretera de Sacramento s/n, La Cañada de San Urbano, 04120 Almeria, Spain, School of Geosciences, University of Aberdeen, Aberdeen, United Kingdom

Verduyn, R.; Geography Division Katholieke Universiteit Leuven GEO-INSTITUTE, Department Earth and Environmental Sciences, Celestijnenlaan 200 E, 3001 Heverlee, Belgium

Verstraeten, G.; Geography Division Katholieke Universiteit Leuven GEO-INSTITUTE, Department Earth and Environmental Sciences, Celestijnenlaan 200 E, 3001 Heverlee, Belgium

Vanmaercke, Matthias ; Université de Liège > Département de géographie > Géographie physique et du quaternaire

Poesen, J.; Geography Division Katholieke Universiteit Leuven GEO-INSTITUTE, Department Earth and Environmental Sciences, Celestijnenlaan 200 E, 3001 Heverlee, Belgium

Language :

English

Title :

Factors controlling sediment yield at the catchment scale in NW Mediterranean geoecosystems

Publication date :

2011

Journal title :

Journal of Soils and Sediments

ISSN :

1439-0108

eISSN :

1614-7480

Publisher :

Springer

Volume :

Issue :

Pages :

690-707

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 28 March 2017

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Bibliography

Abrahams AD (1984) Channel networks: a geomorphological perspective. Water Resour Res 20: 161-188.
Achite M, Touaibia B (2000) Analyse multivariée de la variable 'érosion spécifique': cas du bassin versant de l'Oued Mina (Wilaya de Relizane -Algérie). In: Séminaire International Montpellier 2000 Hydrologie des régions méditerranéennes. Programme Hydrologique International, Documents Techniques en Hydrologie 51, pp 119-127.
Ali FK, de Boer DH (2008) Factors controlling specific sediment yield in the upper Indus River basin, northern Pakistan. Hydrol Process 22: 3102-3114.
Allen PB (1986) Drainage density versus runoff and sediment yield. In: Fourth Federal Interagency Sedimentation Conference, Las Vegas. USGS, pp. 3-38, 33-44.
Arnoldus HMJ (1977) Methodology used to determine the maximum potential average annual soil loss due to sheet and rill erosion in Morocco. FAO Soils Bulletin.
Avendaño Salas C, Cobo Rayán R (1997) Metodología para estimar la erosion de cuencas fluviales a partir de la batimetría de embalses. In: Ibáñez JJ, Valero Garcés BL, Machado C (eds) El paisaje mediterráneo a través del espacio y del tiempo. Implicaciones en la desertificación. Logroño. Geoforma Ediciones, pp 239-257.
Avendaño Salas C, Cobo Rayán R, Gómez Montaña JL, Sanz Montero E (1995) Procedimiento para evaluar la degradación específica (erosión) de cuencas de embalses a partir de los sedimentos acumulados en los mismos. Aplicación al estudio de embalses Españoles. Ingeniería Civil 99: 51-58.
Avendaño Salas C, Cobo Rayán R, Sanz Montero E, Gómez Montaña JL (1997a) Capacity situation in Spanish reservoirs. In: Dix-neuvième Congrès des Grands Barrages, Florence. Commission Internationale Des Grands Barrages, pp 849-862.
Avendaño Salas C, Sanz Montero E, Gómez Montaña JL (1997b) Sediment yield at Spanish reservoirs and its relationship with the drainage basin area. In: Dix-neuvième Congrès des Grands Barrages, Florence. Commission Internationale De Grands Barrages, pp 863-874.
Bazzoffi P, Baldassarre G, Pellegrini S, Bassignana A (1997) Models for prediction of water storage decrease in Italian Reservoirs. In: Shady AM, Kassem A, Delise CE, Bouchard MA (eds) Proceedings of the IX World Water Congress IWRA, 1997. pp 249-252.
Cammeraat LH, Imeson AC (1999) The evolution and significance of soil-vegetation patterns following land abandonment and fire in Spain. Catena 37: 107-127.
Casermeiro MA, Molina JA, de la Cruz Caravaca MT, Hernando Costa J, Hernando Massanet MI, Moreno PS (2004) Influence of scrubs on runoff and sediment loss in soils of Mediterranean climate. Catena 57: 91-107.
CEDEX (1992) Informe sobre la situación de los estudios de aforo de solidos, batimetria y sedimentologia de embalses hasta 1992. Centro de Estudios Hidrográficos del CEDEX, Madrid.
Clark EH (1985) The off-site costs of soil erosion. J Soil Water Conserv 40: 19-22.
Colombo R, Vogt JV, Soille P, Paracchini ML, de Jager A (2007) Deriving river networks and catchments at the European scale from medium resolution digital elevation data. Catena 70: 296-305.
Daniel JRK (1981) Drainage density as an index of climatic geomorphology. J Hydrol 50: 147-154.
de Roo APJ (1998) Modelling runoff and sediment transport in catchments using GIS. Hydrol Process 12: 905-922.
de Roo APJ, Wesseling CG, Ritsema CJ (1996) LISEM: a single event physically-based hydrologic and soil erosion model for drainage basins: I Theory, input and output. Hydrol Process 10: 1107-1117.
de Vente J (2009) Soil erosion and sediment yield in Mediterranean geoecosystems. Scale issues, modelling and understanding. PhD thesis, K. U. Leuven, Leuven, Belgium.
de Vente J, Poesen J, Verstraeten G (2005) The application of semi-quantitative methods and reservoir sedimentation rates for the prediction of basin sediment yield in Spain. J Hydrol 305: 63-86.
de Vente J, Poesen J, Bazzoffi P, van Rompaey A, Verstraeten G (2006) Predicting catchment sediment yield in Mediterranean environments: the importance of sediment sources and connectivity in Italian drainage basins. Earth Surf Process Landf 31: 1017-1034.
de Vente J, Poesen J, Arabkhedri M, Verstraeten G (2007) The sediment delivery problem revisited. Prog Phys Geog 31: 155-178.
de Vente J, Poesen J, Verstraeten G, van Rompaey A, Govers G (2008) Spatially distributed modelling of soil erosion and sediment yield at regional scales in Spain. Global Planet Change 60: 393-415.
Delmas M, Cerdan O, Mouchel J-M, Garcin M (2009) A method for developing a large-scale sediment yield index for European river basins. J Soils Sediments 9: 613-626.
Demmak A (1984) Recherche d'une relation empirique entre apports solides spécifiques et paramètres physico-climatiques des bassins: application au cas algérien. In: Walling DE, Foster SSD, Wurzel P (eds) Challenges in African hydrology and water resources, Harare. IAHS publication No. 144, pp 403-414.
Dendy FE, Bolton GC (1976) Sediment yield-runoff-drainage area relationships in the United States. J Soil Water Conserv 31: 264-266.
Eastman JR (2003) IDRISI Kilimanjaro guide to GIS and image processing; Manual Version, 14th edn. Clark Labs, Worcester.
EEA (2000) CORINE land cover 2000. European Environment Agency http://image2000. jrc. it.
ESB (2004) European Soil Database. European Soil Bureau Network and the European Commission, EUR 19945 EN, http://eusoils. jrc. it.
Flanagan DC, Ascough JC II, Nicks AD, Nearing MA, Lafle JM (1995) Overview of the WEPP erosion prediction model. In: Flanagan DC, Nearing MA (eds) USDA-Water Erosion Prediction Project. Hillslope profile and watershed model documentation, vol NSERL Report 10. USDA, Indiana, pp 1. 1-1. 12.
Flaxman EM (1972) Predicting sediment yield in western United States. J Hydraul Div ASCE 98(12): 2073-2085.
Foster GR, Flanagan DC, Nearing MA, Lane LJ, Risse LM, Finker SC (1995) Hillslope erosion component. In: Flanagan DC, Nearing MA (eds) USDA-water erosion prediction project. Hillslope profile and watershed model documentation, vol NSERL Report 10. USDA, Indiana, pp 11. 11-11. 12.
Fournier F (1960) Climat et érosion: la relation entre l'érosion du sol par l'eau et les précipitations atmosphériques. Presses Universitaires de France, Paris.
García-Ruiz JM (2010) The effects of land uses on soil erosion in Spain: a review. Catena 81: 1-11.
Grauso S, Pagano A, Fattoruso G, De Bonis P, Onori F, Regina P, Tebano C (2008) Relations between climatic-geomorphological parameters and sediment yield in a mediterranean semi-arid area (Sicily, southern Italy). Environ Geol 54: 219-234.
Gyssels G, Poesen J, Bochet E, Li Y (2005) Impact of plant roots on the resistance of soils to erosion by water: a review. Prog Phys Geog 29: 189-217.
Hadley RF, Lal R, Onstad CA, Walling DE, Yair A (1985) Recent developments in erosion and sediment yield studies. International Hydrological Programme (IHP). UNESCO, Paris.
Haregeweyn N, Poesen J, Nyssen J, Verstraeten G, de Vente J, Govers G, Deckers S, Moeyersons J (2005) Specific sediment yield in Tigray-Northern Ethiopia: assessment and semi-quantitative modelling. Geomorphology 69: 315-331.
Harrison CGA (2000) What factors control mechanical erosion rates? Int J Earth Sci 88: 752-763.
Hovius N (1998) Control of sediment supply by large rivers. In: Relative role of Eustasy, climate and tectonism in continental rocks. SEPM Special Publication, pp 3-16.
Ichim I (1990) The relationship between sediment delivery ratio and stream order: a Romanian case study. In: Walling DE, Yair A, Berkovicz S (eds) Erosion, transport and deposition processes, Jerusalem, 1990. IAHS publication 189, pp 79-86.
Jansson MB (1982) Land erosion by water in different climates. Ph. D thesis, UNGI report No. 57, Uppsala University, Sweden.
Kirkby MJ, Jones RJA, Irvine B, Gobin A, Govers G, Cerdan O, van Rompaey AJJ, Le Bissonnais Y, Daroussin J, King D, Montanarella L, Grimm M, Vieillefont V, Puigdefabregas J, Boer M, Kosmas C, Yassoglou N, Tsara M, Mantel S, van Lynden G (2004) Pan-European soil erosion risk assessment: the PESERA Map, Version 1 October 2003. Explanation of Special Publication. No. 73 (S. P. I. 04. 73). European Soil Bureau Research Report No. 16, EUR 21176, Office for Official Publications of the European Communities, Luxembourg.
Langbein WB, Schumm SA (1958) Yield of sediment in relation to mean annual precipitation. Trans Amer Geophys Union 39: 1076-1084.
Lixian W, Lida S, Xiying H, Boging Z, Qingyu W, Guiyun L (1996) Application of regression analysis to the prediction of average annual yield of silt. In: Lixian W (ed) Combating desertification in China. China Forestry Publishing House, pp 210-221.
Ludwig W, Probst J-L (1998) River sediment discharge to the oceans; present-day controls and global budgets. Am J Sci 298: 265-295.
Ludwig W, Probst J-L, Kempe S (1996) Predicting the oceanic input of organic carbon by continental erosion. Global Biogeochem Cycles 10: 23-41.
Michiels P, Gabriels D, Hartmann R (1992) Using the seasonal and temporal precipitation concentration index for characterizing the monthly rainfall distribution in Spain. Catena 19: 43-58.
Molina A, Govers G, Vanacker V, Poesen J, Zeelmaekers E, Cisneros F (2007) Runoff generation in a degraded Andean ecosystem: interaction of vegetation cover and land use. Catena 71: 357-370.
Morgan RPC, Quinton JN, Smith RE, Govers G, Poesen J, Auerswald K, Chisci G, Torri D, Styczen ME (1998) The European Soil Erosion Model (EUROSEM): a dynamic approach for predicting sediment transport from fields and small catchments. Earth Surf Process Land 23: 527-544.
Nash JE, Sutcliffe JV (1970) River flow forecasting through conceptual models part I-a discussion of principles. J Hydrol 10: 282-290.
Oliver JE (1980) Monthly precipitation distribution: a comparative index. Profess Geographer 32: 300-309.
Owens PN, Batalla RJ, Collins AJ, Gomez B, Hicks DM, Horowitz AJ, Kondolf GM, Marden M, Page MJ, Peacock DH, Petticrew EL, Salomons W, Trustrum NA (2005) Fine-grained sediment in river systems: environmental significance and management issues. River Res Appl 21: 693-717.
Poesen J, Hooke JM (1997) Erosion, flooding and channel management in Mediterranean environments of Southern Europe. Prog Phys Geog 21: 157-199.
Poesen J, van Wesemael B, Govers G, Martinez-Fernandez J, Desmet P, Vandaele K, Quine T, Degraer G (1997) Patterns of rock fragment cover generated by tillage erosion. Geomorphology 18: 183-197.
Probst JL, Amiotte-Suchet P (1992) Fluvial suspended sediment transport and mechanical erosion in the Maghreb (North Africa). Hydrol Sci J 37: 621-637.
Rabus B, Eineder M, Roth A, Bamler R (2003) The Shuttle Radar Topography Mission-a new class of digital elevation models acquired by spaceborne radar. ISPRS J Photogramm 57: 241-262.
Ramos MC, Martinez-Casasnovas JA (2004) Nutrient losses from a vineyard soil in northeastern Spain caused by an extraordinary rainfall event. Catena 55: 79-90.
Renard KG, Freimund JR (1994) Using monthly precipitation data to estimate the R-factor in the revised USLE. J Hydrol 157: 287-306.
Restrepo JD, Kjerfve B, Hermelin M, Restrepo JC (2006) Factors controlling sediment yield in a major South American drainage basin: the Magdalena River, Colombia. J Hydrol 316: 213-232.
Roberts PJT (1973) A method of estimating mean annual sediment yields in ungauged catchments. Technical Note No. 44 Department of Water Affairs South Africa, Division of Hydrology.
Rojo Serrano L (2003) Description of the land use changes in relation to type of crops, landscapes and physiographic units involved in the Guadalentin basin. Deliverable 3. 3a. DESERTLINKS, EVK2-CT-2001-00109 www. kcl. ac. uk/projects/desertlinks.
SAS (1999) SAS Online Doc version 8. SAS Institute, Cary, NC, USA. http://v8doc. sas. com/sashtml/.
Schoorl JM, Veldkamp A (2001) Linking land use and landscape process modelling: a case study for the Alora region (south Spain). Agr Ecosyst Environ 85: 281-292.
Shao JX, Tu D (1995) The Jackknife and Bootstrap. Springer, New York.
Steegen A, Govers G, Takken I, Nachtergaele J, Poesen J, Merckx R (2001) Factors controlling sediment and phosphorus export from two Belgian agricultural catchments. J Environ Qual 30: 1249-1258.
Syvitski JPM, Kettner AJ (2007) On the flux of water and sediment into the Northern Adriatic Sea. Cont Shelf Res 27: 296-308.
Syvitski JPM, Milliman JD (2007) Geology, geography, and humans battle for dominance over the delivery of fluvial sediment to the coastal ocean. J Geol 115: 1-19.
Syvitski JPM, Peckham SD, Hilberman R, Mulder T (2003) Predicting the terrestrial flux of sediment to the global ocean: a planetary perspective. Sediment Geol 162: 5-24.
Syvitski JPM, Vörösmarty CJ, Kettner AJ, Green P (2005) Impact of humans on the flux of terrestrial sediment to the global coastal ocean. Science 308: 376-380.
Tamene L, Park SJ, Dikau R, Vlek PLG (2006) Analysis of factors determining sediment yield variability in the highlands of northern Ethiopia. Geomorphology 76: 76-91.
UNEP (1997) World atlas of desertification. United Nations Environment Programme.
Vanmaercke M, Poesen J, Maetens W, de Vente J, Verstraeten G (2011) Sediment yield as a desertification risk indicator. Science of the Total Environment 409 (9): 1715-1725.
van Wesemael B, Cammeraat E, Mulligan M, Burke S (2003) The impact of soil properties and topography on drought vulnerability of rainfed cropping systems in southern Spain. Agr Ecosys Environ 94: 1-15.
Verstraeten G, Poesen J (1999) The nature of small-scale flooding, muddy floods and retention pond sedimentation in central Belgium. Geomorphology 29: 275-292.
Verstraeten G, Poesen J (2001) Factors controlling sediment yield from small intensively cultivated catchments in a temperate humid climate. Geomorphology 40: 123-144.
Verstraeten G, Poesen J, de Vente J, Koninckx X (2003) Sediment yield variability in Spain: a quantitative and semiqualitative analysis using reservoir sedimentation rates. Geomorphology 50: 327-348.
Vogt JV, Colombo R, Bertolo F (2003) Deriving drainage networks and catchment boundaries: a new methodology combining digital elevation data and environmental characteristics. Geomorphology 53: 281-298.
Walling DE (1983) The sediment delivery problem. J Hydrol 65: 209-237.
Walling DE, Kleo AHA (1979) Sediment yields of rivers in areas of low precipitation: a global view. In: IAHS (ed) The hydrology of areas of low precipitation, Canberra, 1979. IAHS publication 128, pp 479-493.
WCD (2000) Dams and development. A new framework for decision-making. Earthscan Publications Ltd., London.
Wilson L (1973) Variations in mean annual sediment yield as a function of mean annual precipitation. Am J Sci 273: 335-349.
Woodward JC (1995) Patterns of erosion and suspended sediment yield in Mediterranean river basins. In: Foster IDL, Gurnell AM, Webb BW (eds) Sediment and water quality in river catchments. Wiley, Chichester, pp 365-389.