Field-Scale Water Flow Simulations Using Ensembles of Pedotransfer Functions for Soil Water Retention

Using pedotransfer functions (PTF) to estimate soil hydraulic properties may be necessary in soil water flow simulations for large-scale projects or in pilot studies. The accuracy of a PTF outside of its development dataset is generally unknown. The existence of multiple models that are developed an...

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Bibliographic Details
Published inVadose zone journal Vol. 5; no. 1; pp. 234 - 247
Main Authors Guber, A.K, Pachepsky, Y.A, Van Genuchten, M.T, Rawls, W.J, Simunek, J, Jacques, D, Nicholson, T.J, Cady, R.E
Format Journal Article
LanguageEnglish
Published Madison Soil Science Society of America 01.02.2006
Soil Science Society
Subjects
Bekkevoort Belgium
Belgium
Brabant Belgium
Brooks and Corey model
bulk density
capillary pressure
central Belgium
depth
equations
Europe
experimental studies
field studies
HYDRUS-1D
HYDRUS-1D software
layered soils
loam soils
mathematical models
moisture
one-dimensional models
pedotransfer functions
Regosols
retention
saturation
scale factor
simulation
simulation models
soil organic matter
soil surveys
soil texture
soil water movement
soil water retention
soils
surveys
transfer functions
unsaturated zone
van Genuchten model
water
water regimes
Western Europe
Belgium
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Summary:Using pedotransfer functions (PTF) to estimate soil hydraulic properties may be necessary in soil water flow simulations for large-scale projects or in pilot studies. The accuracy of a PTF outside of its development dataset is generally unknown. The existence of multiple models that are developed and tested in one region, but may perform relatively poorly in other regions, is also common in meteorology, where multimodel ensemble prediction techniques have been developed (i.e., those using an averaged prediction from several models) to address this problem. The objective of this work was to estimate the applicability of an ensemble of PTFs for water regime simulations. Measured soil water contents and pressure heads of 60 points at five depths in a 6-m transect of a layered loamy soil were collected during an extremely wet year in Belgium. Soil water fluxes were measured with passive capillary lysimeters at two depths. Water retention was measured in the laboratory on samples taken at 60 locations at three depths. Contents of soil textural fractions, organic matter content, and bulk density were averaged across the transect and used as input in the ensemble of 22 published PTFs developed from large datasets in different regions. The HYDRUS-1D software was used to simulate water content time series with (i) each of the PTFs from the ensemble and (ii) the laboratory-measured water retention data of each of the 60 locations. Simulations with the PTF ensemble had, on average, two times smaller errors those from using laboratory data. A possible explanation for this is that the PTF estimation gave substantially better approximations of field water retention than the laboratory data. The ensemble prediction appears to be a promising source of soil hydraulic properties to simulate soil water dynamics.
Bibliography:http://hdl.handle.net/10113/10803
http://dx.doi.org/10.2136/vzj2005.0111
ISSN:1539-1663
1539-1663
DOI:10.2136/vzj2005.0111