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Transit times of water in soil lysimeters from modeling of oxygen-18

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Abstract

A proper description of water pathways and transit times is important in the simulation of groundwater acidification using hydrochemical models. A simple water balance model, describing water flow and transit times in different soil layers, was developed and tested by the use of the stable isotope 18O as a natural tracer in soil lysimeters. Drainage was collected from lysimeters of three depths: 15, 40, and 80 cm, from two sites in the Stubbetorp research basin in south-eastern Sweden. The content of 18O in the precipitation and in the drainage from the lysimeters was measured during 2 yr. 18O was regarded as an ideal tracer, and its concentration in the drainage was modeled using the concentration in the precipitation as input. The percolation from each soil layer was assumed to depend on the inflow and the soil moisture storage in the layer. The most important model parameter, the field capacity, was derived from field information. Sensitivity analysis showed that the model was rather insensitive to other parameter values. Although simple, the model gave good results, both for the flow of water and 18O. The best results were obtained, when ideal mixing in the upper horizons of the soil was combined with piston flow at greater depths. Preferential flow was not found to be of great importance, nor was immobile water. Particle flow velocities and transit times in the soil lysimeters were simulated. The average particle flow velocities were about 0.6 cm d−1. The use of a dynamic model made it possible to simulate the temporal variations in transit times for water in the soil lysimeters. The mean transit times for the 80 cm lysimeter ranged from about 3 to 6 mo with an average value of 4 mo.

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References

  • Andersen, L. J. and Sevel, T.: 1974, ‘Six Years Environmental Tritium Profiles in the Unsaturated and Saturated Zones’, Grönhöj, Denmark, in Isotope techniques in groundwater hydrology, IAEA, Vienna, 3.

    Google Scholar 

  • Andersson, L.: 1988, Nordic Hydrology 19, 1.

    Google Scholar 

  • Bengtsson, L., Saxena, R., and Dressie, Z.: 1987, Hydrological Sciences Journal 32, 497.

    Google Scholar 

  • Bergström, S.: 1975, Nordic Hydrology 6, 73.

    Google Scholar 

  • Bergström, S.: 1976, Development and Application of a Conceptual Runoff Model for Scandinavian Catchments, SMHI Report Nr RHO 7, Norrköping, Sweden.

  • Bergström, S. and Sandberg, G.: 1983, Nordic Hydrology 14, 71.

    Google Scholar 

  • Bergström, S., Carlsson, B., Sandberg, G., and Maxe, L.: 1985, Nordic Hydrology 16, 89.

    Google Scholar 

  • Beven, K. and Germann, R: 1982, Water Resources Research 18, 1311.

    Google Scholar 

  • Bolin, B. and Rodhe, H.: 1973, Tellus 25, 58.

    Google Scholar 

  • Cosby, B. J., Wright, R. F., Hornberger, G. M., and Galloway, J. N.: 1985, Water Resources Research 21, 1591.

    Google Scholar 

  • Dinger, T., Payne, B. R., Florkowski, T., Martinec, J., and Tongiorgi, E.: 1970, Water Resources Research 6, 110.

    Google Scholar 

  • Dinger, T. and Davis, G. H.: 1984, Journal of Hydrology 68, 95.

    Google Scholar 

  • Eriksson, B.: 1981, Den potentiella evapotranspirationen i Sverige, The potential evapotranspiration in Sweden, SMHI Report No. RMK 28, Norrköping, Sweden (in Swedish with English summary).

    Google Scholar 

  • Eriksson, E.: 1963, Tellus 15, 303.

    Google Scholar 

  • Gamble, B. F., Eckstein, Y., and Edwards, W. M.: 1990, Journal of Hydrology 113, 1.

    Google Scholar 

  • Gherini, S. A., Mok, L., Hudson, R. J., Davis, G. F., Chen, C. W., and Goldstein, R. A.: 1985, Water, Air, and Soil Pollution 26, 425.

    Google Scholar 

  • Herrmann, A., Lehrer, M., and Stichler, W.: 1981, Nordic Hydrology 12, 309.

    Google Scholar 

  • Hooper, R. P., Stone, A., Christophersen, N., de Grosbois, E. and Seip, H. M.: 1988, Water Resources Research 24, 1308.

    Google Scholar 

  • Jansson, P.-E. and Halldin, S.: 1979, ‘Model for Annual Water and Energy Flow in a Layered Soil’, in Halldin S. (ed.) Comparison of Forest Water and Energy Exchange Models, International Society for Ecological Modeling, Copenhagen, 145.

    Google Scholar 

  • Lindström, G. and Rodhe, A.: 1986, Nordic Hydrology 17, 325.

    Google Scholar 

  • Lindström, G., Rodhe, A., and de Man, B.: 1990, ‘Transit Times for Water in Till Basins Estimated by a Distributed Model and Oxygen-18’, In NHP-rapport nr. 26, Nordisk Hydrologisk Förening, 94.

  • Maloszewski, P. and Zuber, A.: 1982, Journal of Hydrology 57, 207.

    Google Scholar 

  • Maloszewski, P., Rauert, W., Stichler, W., and Herrmann, A.: 1983, Journal of Hydrology 66, 319.

    Google Scholar 

  • Rodhe, A.: 1987, The Origin of Streamwater Traced by Oxygen-18, Uppsala University, Department of Physical Geography, Division of Hydrology, Report Series A, No. 41.

  • Saxena, R. K.: 1987, Oxygen-18 Fractionation in Nature and Estimation of Groundwater Recharge, Uppsala University, Department of Physical Geography, Division of Hydrology, Report Series A, No. 40.

  • Sklash, M.G. and Farvolden, R. N.: 1979, Journal of Hydrology 43, 45.

    Google Scholar 

  • Stone, A. and Seip, H. M.: 1989, Ambio. 18, 192.

    Google Scholar 

  • Sverdrup, H. and Warfvinge, P. G.: 1988, ‘Chemical Weathering of Minerals in the Gårdsjön Catchment in Relation to a Model Based on Laboratory Rate Coefficients’, in Nilsson, J. and Grennfeldt, P. (eds.) Critical Loads for Sulphur and Nitrogen, Report from a workshop held at Skokloster, Sweden 19–24 March, 1988. Nordic Council of Ministers, Miljörapport 1988:15.

    Google Scholar 

  • Turner, J. V., MacPherson, D. K., and Stokes, R. A.: 1987, Journal of Hydrology 94, 143.

    Google Scholar 

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Lindström, G., Rodhe, A. Transit times of water in soil lysimeters from modeling of oxygen-18. Water Air Soil Pollut 65, 83–100 (1992). https://doi.org/10.1007/BF00482751

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  • DOI: https://doi.org/10.1007/BF00482751

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