Soil & Water Res., 2009, 4(10):S14-S21 | DOI: 10.17221/477-SWR

Variability of saturated hydraulic conductivities in the agriculturallycultivated soils

Vlasta ©TEKAUEROVÁ, Vladimír MIKULEC
Institute of Hydrology, Slovak Academy of Sciences, Bratislava, Slovakia

The knowledge of the moisture conditions in a variably saturated zone of soil and their management is one of the main possibilities that allow the agronomists to raise significantly the fertility of soils. A progressive scientific method for describing the moisture conditions in a variably saturated zone uses a numerical simulation on a mathematical model. The accuracy of the outputs from the model (i.e. moisture profiles) depends mainly, besides the physical and mathematical structures of the model, on the accuracy of the input data. The upper boundary condition comprises the climate and phenological parameters. The initial condition is represented by the moisture profile at the beginning of the simulation and by the main hydrophysical properties of the soil. One of the main hydrophysical properties of soil is the value of the saturated hydraulic conductivity (K). This study is aimed at the determination of its temporal variability, keeping in mind also its areal one (with respect to the sampling data from various verticals). Several methods exist for the determination of the K values. In this study, a laboratory method with the falling head method (Klabor) was used. The areal-temporal variability of the Klabor values was evaluated for the vegetation period of the year 2003 on the locality Most pri Bratislave.

Keywords: saturated hydraulic conductivity; method with falling head method; frequency function; distribution function

Published: December 31, 2009  Show citation

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©TEKAUEROVÁ V, MIKULEC V. Variability of saturated hydraulic conductivities in the agriculturallycultivated soils. Soil & Water Res. 2009;4(Special Issue 2):S14-21. doi: 10.17221/477-SWR.
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    References

    1. Bergström L., Jarvis N.J. (1993): Leaching of dichlorprop, bentazon, and 36 Cl in indisturbed field lysimeters of different agricultural soils. Weed Science, 41: 251-161. Go to original source...
    2. Beven K., German P. (1982): Macropores and water flow in soils. Water Resources Research, 18: 1311-1325. Go to original source...
    3. Farkas Cs., Birkás M., Várallyay Gy. (2009): Soil tillage systems to reduce the harmful effect of extreme weather and hydrological situations. Biologia, 64: 624-628. Go to original source...
    4. Mikulec V. (2005): Influence of processing of the measured hydrophysical characteristics upon the simulation results of the vertical water motion in the unsaturated soil zone. Acta Hydrologica Slovaca, 6: 283-292. (in Slovak with English summary)
    5. Rao P.S.C., Green R.E., Balabsubramanian V., Kenehiro Y. (1974): Field study of solute movement in highly aggregated Oxisol with intermittent flooding. II. Picloram. Journal of Environmental Quality, 3: 197-201. Go to original source...
    6. Steenhuis T.S., Parlange J.-Y. (1991): Preferential flow in structured and sandy soils. In: Gish T., Shirmohammadi A. (eds): Proc. National Symposium on Preferential Flow., ASAE, St. Joseph, 12-21.
    7. ©tekauerová V., ©útor J. (2000): The role of monitoring in numerical simulation of the aeration soil zone water regime. Acta Hydrologica Slovaca, 2: 203-212. (in Slovak with English summary)
    8. ©tekauerová V., Nagy V. (2002): Influence of climate conditions on security of necessary water for vegetation in various ecosystems. In: Polution and Water Resources. Columbia University Seminar Proceedings, HAS, Budapest, 324-337. ©útor J. (1986): Areal variability of the soil hydrophysical characteristics - the hydraulic soil properties. Vodohospodársky èasopis, 34: 284-313. (in Slovak with English summary)
    9. ©útor J., Majerèák J., ©tekauerová V. (2002): Quantification of water store in soil aeration zone in agricultural ecosystems using data files from numerical simulation. In: Polution and Water Resources. Columbia University Seminar Proceedings. HAS, Budapest, 352-361.

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