Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Soil Research Soil Research Society
Soil, land care and environmental research
RESEARCH ARTICLE

Soil organic carbon losses by water erosion in a Mediterranean watershed

Ahmet Cilek
+ Author Affiliations
- Author Affiliations

Cukurova University, Landscape Architecture Department, 01330 Adana, Turkey. Email: acilek@cu.edu.tr

Soil Research 55(4) 363-375 https://doi.org/10.1071/SR16053
Submitted: 23 February 2016  Accepted: 18 November 2016   Published: 15 December 2016

Abstract

Soil organic carbon (SOC) is one of the primary elements required in the functioning of ecosystems. Soil erosion, a major mechanism of land degradation, removes SOC and transfers it to the hydrosphere or the atmosphere, thereby affecting key ecosystem functions and services. The Mediterranean region is highly susceptible to land degradation because of erosion due to heavy rains following long, dry, hot summers. Although the Mediterranean landscape typically has a high altitude and incline, the soil is brittle and soft and is easily washed away by rain. Thus, vast regions in Turkey have been afflicted by this type of soil degradation. This study aimed to (1) estimate the temporal distribution of water erosion in the Seyhan River Basin, (2) assess the spatial distribution of SOC and (3) estimate the depletion of SOC through soil erosion using the Pan-European Soil Erosion Risk Assessment model, a physically based, regionally scaled soil erosion model.

The annual amount of soil eroded from the Seyhan River Basin is estimated to be 7.8 million tonnes per hectare (t ha–1 year–1). The amount of fertile soil loss from agricultural areas is ~1.2 million tonnes per year. The maximum amount of soil erosion occurs in maintenance scrubland and degraded forest areas, contributing to 68% of erosion, followed by that in agricultural land, contributing to 27% of erosion, with the remaining in forests and urban areas.

Additional keywords: Mediterranean environment, PESERA, SOC, soil erosion.


References

Albergel J, Mansouri T, Zante P, Ben Mamou A, Abdeljaoued S (2006) Organic carbon in the sediments of hill dams in a semiarid Mediterranean area. In ‘Soil erosion and carbon dynamics. Advances in Soil Science’. (Eds EJ Roose, R Lal, C Feller, B Barthes, BA Stewart) pp. 289–299. (Taylor & Francis: Boca Raton, FL)

Arrouays D, Deslais W, Badeau V (2001) The carbon content of topsoil and its geographical distribution in France. Soil Use and Management 17, 7–11.
The carbon content of topsoil and its geographical distribution in France.Crossref | GoogleScholarGoogle Scholar |

Batjes NH (1996) Total carbon and nitrogen in the soils of the world. European Journal of Soil Science 47, 151–163.
Total carbon and nitrogen in the soils of the world.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK28XlslKnsLo%3D&md5=3d6d34dc062280091d5d5974fb2e5c4fCAS |

Batjes NH (1997) A world data set of derived soil properties by FAO–UNESCO soil unit for global modelling. Soil Use and Management 13, 9–16.
A world data set of derived soil properties by FAO–UNESCO soil unit for global modelling.Crossref | GoogleScholarGoogle Scholar |

Batjes NH, Sombroek WG (1997) Possibilities for carbon sequestration in tropical and subtropical soils. Global Change Biology 3, 161–173.
Possibilities for carbon sequestration in tropical and subtropical soils.Crossref | GoogleScholarGoogle Scholar |

Berberoglu S, Satir O, Atkinson PM (2009) Mapping percentage tree cover from Envisat MERIS data using linear and non-linear techniques. International Journal of Remote Sensing 30, 4747–4766.
Mapping percentage tree cover from Envisat MERIS data using linear and non-linear techniques.Crossref | GoogleScholarGoogle Scholar |

Boix-Fayos C, de Vente J, Albaladejo J, Martinez-Mena M (2009) Soil carbon erosion and stock as affected by land use changes at the catchment scale in Mediterranean ecosystems. Agriculture, Ecosystems & Environment 133, 75–85.
Soil carbon erosion and stock as affected by land use changes at the catchment scale in Mediterranean ecosystems.Crossref | GoogleScholarGoogle Scholar |

Breuning-Madsen H, Jones RJA (1995) Soil profile analytical database for the European Union. Danish Journal of Geography 95, 49–58.
Soil profile analytical database for the European Union.Crossref | GoogleScholarGoogle Scholar |

Brown LR (1981) Eroding the base of civilization. Journal of Soil and Water Conservation 36, 255–260.

Brown LR (1984) The global loss of topsoil. Journal of Soil and Water Conservation 39, 162–165.

Chaplot V, Poesen J (2012) Sediment, soil organic carbon and runoff delivery at various spatial scales. Catena 88, 46–56.
Sediment, soil organic carbon and runoff delivery at various spatial scales.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXhsVehsLjF&md5=99a56d6145ac90c5b388ce8ded0e2908CAS |

Chaplot VAM, Rumpel C, Valentin C (2005) Water erosion impact on soil and carbon redistributions within uplands of Mekong River. Global Biogeochemical Cycles 19, GB4004.
Water erosion impact on soil and carbon redistributions within uplands of Mekong River.Crossref | GoogleScholarGoogle Scholar |

Cilek A, Berberoglu S, Kirkby M, Irvine B, Donmez C, Erdogan MA (2015) Erosion modelling in a Mediterranean subcatchment under climate change scenarios using Pan-European Soil Erosion Risk Assessment (PESERA). The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XL-7, 359–365.
Erosion modelling in a Mediterranean subcatchment under climate change scenarios using Pan-European Soil Erosion Risk Assessment (PESERA).Crossref | GoogleScholarGoogle Scholar |

Cilek A, Berberoglu S, Donmez C (2016) Evaluation of rainfall-runoff models for Mediterranean subcatchments. The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLI-B8, 321–325.
Evaluation of rainfall-runoff models for Mediterranean subcatchments.Crossref | GoogleScholarGoogle Scholar |

Daroussin J, King D (1997) A pedotransfer rules database to interpret the Soil Geographical Database of Europe for environmental purposes. In ‘The use of pedotransfer functions in soil hydrology research in Europe’. (Eds A Bruand, O Duval, H Wosten, A Lilly) pp. 25–40. European Soil Bureau Research Report No. 3, EUR 17307 EN. (INRA: Orleans)

Davis PH (1965) ‘Flora of Turkey and the east Aegean islands. Vol. 1–9.’ (Edinburgh University Press: Edinburgh)

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 and Planetary Change 60, 393–415.
Spatially distributed modelling of soil erosion and sediment yield at regional scales in Spain.Crossref | GoogleScholarGoogle Scholar |

Del Galdo I, Six J, Peressotti A, Cotrufo MF (2003) Assessing the impact of land-use change on soil C sequestration in agricultural soils by means of organic matter fractionation and stable C isotopes. Global Change Biology 9, 1204–1213.
Assessing the impact of land-use change on soil C sequestration in agricultural soils by means of organic matter fractionation and stable C isotopes.Crossref | GoogleScholarGoogle Scholar |

Donmez C, Berberoglu S, Curranbet PJ (2011) Modelling the current and future spatial distribution of NPP in a Mediterranean watershed. International Journal of Applied Earth Observation and Geoinformation 13, 336–345.
Modelling the current and future spatial distribution of NPP in a Mediterranean watershed.Crossref | GoogleScholarGoogle Scholar |

Dregne HE (1982) Historical perspective of accelerated erosion and effect on world civilization. In ‘Determinants of soil loss tolerance’. (Ed. BL Schmidt) pp. 1–14. (American Society of Agronomy, Soil Science Society of America: Madison, WI)

Eckholm EP (1976) ‘Losing ground.’ (Norton: New York, NY)

Evrendilek F, Berberoglu S, Taskinsu-Meydan S, Yılmaz E (2006) Quantifying carbon budget of conifer Mediterranean forest ecosystems, Turkey. Environmental Monitoring and Assessment 119, 527–543.
Quantifying carbon budget of conifer Mediterranean forest ecosystems, Turkey.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XnslKqt7g%3D&md5=94e6cb48ced1fcc84c3f4164ea745ec1CAS |

FAO (1985) Guidelines: land evaluation for irrigated agriculture. Soils Resources, Management and Conservation Service FAO Land and Water Development Division. Food and Agriculture Organization of The United Nations, Rome.

FAO–UNESCO (1974) FAO–UNESCO soil map of the world: legend. UNESCO, Paris.

FAO–UNESCO–ISRIC (1990) FAO–UNESCO soil map of the world: revised legend. World Soil Resources Report No. 60. FAO, Rome.

Fujihara Y, Tanaka K, Nagano T, Watanabe T, Kojiri T (2007) International Congress River Basin Management. Republic of Turkey Ministry of Energy and Natural Resources General Directorate of State Hydraulic Works, Antalya.

Global assessment of soil degradation (GLASOD) (1990) ‘Global assessment of soil degradation. World map.’ (ISRIC: Wageningen)

Goidts E, van Wesemael B (2007) Regional assessment of soil organic carbon changes under agriculture in Southern Belgium (1955–2005). Geoderma 141, 341–354.
Regional assessment of soil organic carbon changes under agriculture in Southern Belgium (1955–2005).Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2sXhtVWjsrfJ&md5=0fc62e47e1ba32d76e54733c0f90d263CAS |

Guo LB, Gifford RM (2002) Soil carbon stocks and land use change: a meta-analysis. Global Change Biology 8, 345–360.
Soil carbon stocks and land use change: a meta-analysis.Crossref | GoogleScholarGoogle Scholar |

Howard PJA, Loveland PJ, Bradley RI, Dry FT, Howard DM, Howard DC (1995) The carbon content of soil and its geographical distribution in Great Britain. Soil Use and Management 11, 9–15.
The carbon content of soil and its geographical distribution in Great Britain.Crossref | GoogleScholarGoogle Scholar |

Ito A (2007) Simulated impacts of climate and landcover change on soil erosion and implication for the carbon cycle, 1901 to 2100. Geophysical Research Letters 34, L09403.

Izaurralde RC, Williams JR, Post WM, Thomson AM, McGill WB, Owens LB, Lal R (2007) Long-term modeling of soil C erosion and sequestration at the small watershed scale. Climatic Change 80, 73–90.

Jacinthe PA, Lal R, Owens LB, Hothem DL (2004) Transport of labile carbon in runoff as affected by land use and rainfall characteristics. Soil & Tillage Research 77, 111–123.
Transport of labile carbon in runoff as affected by land use and rainfall characteristics.Crossref | GoogleScholarGoogle Scholar |

Jia S (2010) Soil organic carbon loss through water erosion in Loess Hilly region of northwestern China. Project supported by the Doctor Funding of Henan University of Science and Technology.

Jones RJA, Hollis JM (1996) Pedotransfer rules for environmental interpretations of the EU Soil Database. In ‘Soil databases to support sustainable development’. (Eds C Le Bas, M Jamagne) pp. 125–133. European Soil Bureau Research Report No. 2, EUR 16371 EN. (Office for Official Publications of the European Communities: Luxembourg)

Jones RJA, Hiederer R, Rusco E, Montanarella L (2005) Estimating organic carbon in the soils of Europe for policy support. European Journal of Soil Science 56, 655–671.
Estimating organic carbon in the soils of Europe for policy support.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXhtFGlsbrE&md5=8a4d664f13f55f02355bce7ef774a39dCAS |

Kirkby MJ, Le Bissonais Y, Coulthard TJ, Daroussin J, McMahon MD (2000) The development of land quality indicators for soil degradation by water erosion. Agriculture, Ecosystems & Environment 81, 125–135.
The development of land quality indicators for soil degradation by water erosion.Crossref | GoogleScholarGoogle Scholar |

Kirkby MJ, Gobin A, Irvine B (2003) Pan European Soil Erosion Risk Assessment. Deliverable 5: PESERA model strategy, land use and vegetation growth, European Soil Bureau. Available at http://eusoils.jrc.it/ [Accessed 5 November 2016].

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 GJ, Huting J (2004) ‘Pan-European Soil Erosion Risk Assessment: the PESERA map, Version 1 October 2003. Explanation of Special Publication Ispra 2004 No. 73 (S.P.I.04.73).’ European Soil Bureau Research Report No. 16, EUR 21176, and 1 map in ISO B1 format. (Office for Official Publications of the European Communities: Luxembourg)

Kirkels FMSA, Cammeraat LH, Kuhn NJ (2014) The fate of soil organic carbon upon erosion, transport and deposition in agricultural landscapes—a review of different concepts. Geomorphology 226, 94–105.
The fate of soil organic carbon upon erosion, transport and deposition in agricultural landscapes—a review of different concepts.Crossref | GoogleScholarGoogle Scholar |

Kwaad FJPM, Van der Zijp M, Van Dijk PM (1998) Soil conservation and maize cropping systems on sloping loess soils in The Netherlands. Soil & Tillage Research 46, 13–21.
Soil conservation and maize cropping systems on sloping loess soils in The Netherlands.Crossref | GoogleScholarGoogle Scholar |

Lal R (1995) Global soil erosion by water and carbon dynamics. In ‘Soils and global change’. (Eds R Lal, JM Kimble, E Levine, BA Stewart) pp. 131–142. (CRC Press: Boca Raton, FL)

Lal R (2002) Soil carbon dynamics in cropland and range land. Environmental Pollution 116, 353–362.
Soil carbon dynamics in cropland and range land.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXovVersLk%3D&md5=d4d4913938012df8acb8d8219afd00d9CAS |

Lal R (2003) Soil erosion and the global carbon budget. Environment International 29, 437–450.
Soil erosion and the global carbon budget.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXivVOnsLc%3D&md5=31c81361fd43dfea86f5aa5a54b1dfb2CAS |

Le Bissonnais Y, Jamagne M, Lambert JJ, Le Bas C, Daroussin J, King D, Cerdan O, Leonard J, Bresson L-M, Jones RJA (2005) Pan-European soil crusting and erodibility assessment from the European Soil Geographical Database using pedotransfer rules. Advances in Environmental Monitoring and Modelling 2, 1–15.

Lettens S, van Orshoven J, van Wesemael B, Muys B (2004) Soil organic and inorganic carbon contents of landscape units in Belgium derived using data from 1950 to 1970. Soil Use and Management 20, 40–47.
Soil organic and inorganic carbon contents of landscape units in Belgium derived using data from 1950 to 1970.Crossref | GoogleScholarGoogle Scholar |

Li Y, Xia Y, Lei Y, Deng Y, Chen H, Sha L, Cao M, Deng X (2015) Estimating changes in soil organic carbon storage due to land use changes using a modified calculation method. iForest 8, 45–52.

Licciardello F, Govers G, Cerdan O, Kirkby MJ, Vacca A, Kwaad FJPM (2009) Evaluation of the PESERA model in two contrasting environments. Earth Surface Processes and Landforms 34, 629–640.
Evaluation of the PESERA model in two contrasting environments.Crossref | GoogleScholarGoogle Scholar |

Liu XB, Han XZ, Herbert SJ, Xing B (2003) Dynamics of soil organic carbon under different agricultural management systems in the black soil of China. Communications in Soil Science and Plant Analysis 34, 973–984.
Dynamics of soil organic carbon under different agricultural management systems in the black soil of China.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXjs1aqtbc%3D&md5=e87609aacf5cda8dcc600fa15a97cbaeCAS |

Lowdermilk WC (1953) Conquest of the land through seven thousand years. USDA Bulletin No. 99. US Department of Agriculture, Soil Conservation Service, Washington, DC.

Mantel S, Schulp CJE, van den Berg M (2014) Modelling of soil degradation and its impact on ecosystem services globally. Part 1: a study on the adequacy of models to quantify soil water erosion for use within the IMAGE modeling framework Report 2014/xx, ISRIC—World Soil Information, Wageningen.

Meersmans J, De Ridder F, Canters F, De Baets S, Van Molle M (2008) A multiple regression approach to assess the spatial distribution of soil organic carbon (SOC) at the regional scale (Flanders, Belgium). Geoderma 143, 1–13.

Meydan ST, Evrendilek F, Berberoglu S, Donmez C (2010) Modeling above-ground litterfall in eastern Mediterranean conifer forests using fractional tree cover, and remotely sensed and ground data. Applied Vegetation Science 13, 485–497.
Modeling above-ground litterfall in eastern Mediterranean conifer forests using fractional tree cover, and remotely sensed and ground data.Crossref | GoogleScholarGoogle Scholar |

Olson GW (1981) Archaeology: lessons on future soil use. Journal of Soil and Water Conservation 36, 261–264.

Richards LA, Wadleigh CH (1952). Soil water and plant growth. In ‘Soil physical conditions and plant growth’. (Ed. BT Shaw) pp. 74–251. American Society of Agronomy Series Monographs, Volume II. (Academic Press: New York, NY)

Rusco E, Jones RJA, Bidoglio G (2001) Organic matter in the soils of Europe: present status and future trends. EUR 20556 EN. (Office for Official Publications of the European Communities: Luxembourg)

Satir O, Berberoglu S (2016) Crop yield prediction under soil salinity using satellite derived vegetation indices. Field Crops Research 192, 134–143.
Crop yield prediction under soil salinity using satellite derived vegetation indices.Crossref | GoogleScholarGoogle Scholar |

Satir O, Berberoglu S, Donmez C (2016) Mapping regional forest fire probability using artificial neural network model in a Mediterranean forest ecosystem. Geomatics, Natural Hazards & Risk 7, 1645–1658.
Mapping regional forest fire probability using artificial neural network model in a Mediterranean forest ecosystem.Crossref | GoogleScholarGoogle Scholar |

Smith P, Powlson DS, Smith JU, Falloon P, Coleman K (2000a) Meeting the UK’s climate change commitments: options for carbon mitigation on agricultural land. Soil Use and Management 16, 1–11.
Meeting the UK’s climate change commitments: options for carbon mitigation on agricultural land.Crossref | GoogleScholarGoogle Scholar |

Smith P, Powlson DS, Smith JU, Falloon P, Coleman K (2000b) Revised estimates of the carbon mitigation potential of UK agricultural land. Soil Use and Management 16, 293–295.
Revised estimates of the carbon mitigation potential of UK agricultural land.Crossref | GoogleScholarGoogle Scholar |

Smith SV, Sleezer RO, Renwick WH, Buddemeier RW (2005) Fates of eroded soil organic carbon: Mississippi basin case study. Ecological Applications 15, 1929–1940.
Fates of eroded soil organic carbon: Mississippi basin case study.Crossref | GoogleScholarGoogle Scholar |

Turbé A, De Toni A, Benito P, Lavelle P, Lavelle P, Ruiz N, Van der Putten WH, Labouze E, Mudgal S (2010) Soil biodiversity: functions, threats and tools for policy makers. Bio Intelligence Service, IRD, NIOO, Report for European Commission (DG Environment).

USDA (1997) ‘National resources inventory.’ (USDA: Washington, DC)

Vacca A, Loddo S, Ollesch G, Puddu R, Serra G, Tomasi D, Aru A (2000) Measurement of runoff and soil erosion in three areas under different land use in Sardinia (Italy). Catena 40, 69–92.
Measurement of runoff and soil erosion in three areas under different land use in Sardinia (Italy).Crossref | GoogleScholarGoogle Scholar |

Van Oost K, Quine TA, Govers G, De Gryze S, Six J, Harden JW, Ritchie JC, McCarty GW, Heckrath G, Kosmas C, Giraldez JV, da Silva JRM, Merckx R (2007) The impact of agricultural soil erosion on the global carbon cycle. Science 318, 626–629.
The impact of agricultural soil erosion on the global carbon cycle.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2sXhtF2rsbnF&md5=1c3185a674eb10877a7d46223d34041fCAS |

Van Ranst E, Thomasson AJ, Daroussin J, Hollis JM, Jones RJA, Jamagne M, King D, Vanmechelen L (1995) Elaboration of an extended knowledge database to interpret the 1 : 1,000,000 EU Soil Map for environmental purposes. In ‘European Land Information Systems for Agro-environmental Monitoring’. (Eds D King, RJA Jones, AJ Thomasson) pp. 71–84. EUR 16232 EN. (Office for Official Publications of the European Communities: Luxembourg)

Wilson B, Puri G (2001) A comparison of pinewood and moorland soils in the Abernethy Forest Reserve, Scotland. Global Ecology and Biogeography 10, 291–303.
A comparison of pinewood and moorland soils in the Abernethy Forest Reserve, Scotland.Crossref | GoogleScholarGoogle Scholar |

Young CJ, Liu S, Schumacher JA, Schumacher TE, Kaspar TC, McCarty GW, Napton D, Jaynes DB (2014) Evaluation of a model framework to estimate soil and soil organic carbon redistribution by water and tillage using 137Cs in two U.S. Midwest agricultural fields. Geoderma 232–234, 437–448.
Evaluation of a model framework to estimate soil and soil organic carbon redistribution by water and tillage using 137Cs in two U.S. Midwest agricultural fields.Crossref | GoogleScholarGoogle Scholar |