Abstract
Accelerated eutrophication of surface water is often caused by high phosphorus (P) losses from agricultural fields. Long-term measurements of P concentrations from arable fields are therefore important for understanding of processes and key factors behind losses. Unfortunately, long-time series are difficult to compare due to high variablity, non-normal distribution, precipitation variability and flow relatedness. The objective was to use locally weighted scatterplot smoothing (LOWESS) and Seasonal Kendall Test to account for discharge effects on concentrations of P forms and suspended soil material, and to identify trends for seven agricultural fields included in a Swedish water quality monitoring program. Soil P content and sorption capacity governed concentrations and losses of dissolved reactive phosphorus (DRP). Other factors, such as preferential flow may influence the importance of these factors. Suspended soil material and unreactive phosphorus (UP) concentrations in water discharge depended on soil texture, slope of the field and total soil P content. Statistically significant trends in concentrations of different P forms were found for two fields. These trends are probably a consequence of changes in P additions and soils P saturation levels.
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References
Börling, K., Otabbong, E. and Barberis, E.: 2001, ‘Phosphorus sorption in relation to soil properties in some cultivated Swedish soils’, Nutr. Cycl. Agroecosys. 59, 39–46.
Cleveland, W.S.: 1979, ‘Robust locally weighted regression and smoothing scatterplots’, J. Am. Stat. Assoc. 74, 829–836.
Djodjic, F., Bergström, L., Ulén, B. and Shirmohammadi, A.: 1999, ‘Mode of transport of surface-applied phosphorus-33 through a clay and sandy soil’, J. Environ. Qual. 28, 1273–1382.
Djodjic, F., Ulén, B. and Bergström, L.: 2000, ‘Temporal and spatial variations of phosphorus losses and drainage in a structured clay soil’, Water Res. 34, 1687–1695.
Égnér, H., Riehm, H. and Domingo, W.R.: 1960, ‘Untersuchungen über die chemische Bodenanalyse als Grundlage für die Beurteilung des Nährst offzustandes der Böden. II. Chemische Extraktions-methoden zur Phosphor-und Kaliumbestimmung’ (in German) Kung: Landbrukshögsk. Annal. 26, 199–215.
Evans, C.D. and Jenkins, A.: 2000, ‘Surface water acidification in the South Pennines II: Temporal trends’, Environ. Pollut. 109, 21–34.
Gustafson, A., Gustavsson, A.S. and Torstensson, G.: 1984, ‘Intensitet och varaktighet hos avrinning från åkermark’, SLU, Avdelningen för vattenvårdslära Ekohydrologi 16. (In Swedish).
Helsel, D.R. and Hirsch, R.M.: 1992, ‘Statistical methods in water resources’, Stud. Environ. Sci. 49, 285–294.
Hirsch, R.M., Slack, J.R. and Smith, R.A.: 1982, ‘Techniques of trend analysis for monthly water quality data’, Water Resour. Res. 18, 107–121.
Johansson, G. and Ulén, B.: 2002, ‘Observationsfält på åkermark’, SLU, Avdelningen f\(\dot o\)r vattenvårdslära. Tekninsk rapport 68. (In Swedish).
KLS (Kungliga Lantbruksstyrelse): 1965, Kungliga Lantbruksstyrelsens kungörelse med (5) bestämmelser f\(\dot o\)r undersökning av jord vid statens lantbrukskemiska kontrollanstalt och lantbrukskemisk kontrollstation och lantbrukskemisk station med av staten fastställda stadgar. Kungliga Lantbruksstyrelsens Kungörelsen nr. 1.
Kyllmar, K. and Ulén, B.: 1998, ‘The Swedish Monitoring Programme’, in L.Øygarden, and P. Botterweg, Measuring Runoff and Nutrient Losses from Agricultural Land in Nordic Countries, TemaNord 575, 67–71.
Larsen, S.E., Kronvang, B., Windolf, J. and Svendsen, L.M.: 1999, ‘Trends in diffuse nutrient concentrations and loading in Denmark: Statistical trend analysis of stream monitoring data’, Water Sci. Techno. 39, 197–205.
Morgan, M.A.: 1997, ‘The Behaviour of Soil and Fertilizer Phosphorus’, in H. Tunney, O.T. Carton, P.C. Brookes, and A.E. Johnston (eds), Phosphorus Loss from Soil to Water, CAB International, Wallingford, pp. 137–149.
Schindler, D.W.: 1977, ‘Evolution of phosphorus in lakes’, Science 195, 260–262.
Sen, P.K.: 1968, ‘Estimates of the regression coefficient based on Kendall’s tau’, J. Am. Stat. Assoc. 63, 1379–1389.
Sharpley, A.N. and Rekolainen, S.: 1997, ‘Phosphorus in Agriculture and its Environmental Implications’, in H. Tunney, O.T. Carton, P.C. Brookes and A.E. Johnston (eds), Phosphorus Loss from Soil to Water, CAB International, Wallingford, pp. 1–54.
Soulsby, C., Malcolm, R., Gibbins, C. and Dilks, C.: 2001, ‘Seasonality, water quality trends and biological responses in four streams in the Cairngorm Mountains, Scotland’, Hydrol. Earth Syst. Sci. 5, 433–450.
Turner, B.L. and Haygarth, P.M.: 2000, ‘Phosphorus forms and concentrations in leachate under four grassland soil types’, Soil Sci. Soc. Am. J. 64, 1090–1099.
Ulén, B.: 1986, ‘Lakning av fosfor ur jordar’, SLU, Avdelningen för vattenvårdslära Ekohydrologi 21. (In Swedish).
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Djodjic, F., Bergström, L. Phosphorus losses from arable fields in Sweden—effects of field-specific factors and long-term trends. Environ Monit Assess 102, 103–117 (2005). https://doi.org/10.1007/s10661-005-2689-y
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DOI: https://doi.org/10.1007/s10661-005-2689-y