Publication date: 1 April 2018
Source:Geoderma, Volume 315
Author(s): Yi Liu, Yuefen Li, Paul Harris, Laura M. Cardenas, Robert M. Dunn, Hadewij Sint, Phil J. Murray, Michael R.F. Lee, Lianhai Wu
In this study, we evaluated the ability of the SPACSYS model to simulate water run-off, soil moisture, N2 O fluxes and grass growth using data generated from a field of the North Wyke Farm Platform. The field-scale model is adapted via a linked and grid-based approach (grid-to-grid) to account for not only temporal dynamics but also the within-field spatial variation in these key ecosystem indicators. Spatial variability in nutrient and water presence at the field-scale is a key source of uncertainty when quantifying nutrient cycling and water movement in an agricultural system. Results demonstrated that the new spatially distributed version of SPACSYS provided a worthy improvement in accuracy over the standard (single-point) version for biomass productivity. No difference in model prediction performance was observed for water run-off, reflecting the closed-system nature of this variable. Similarly, no difference in model prediction performance was found for N2 O fluxes, but here the N2 O predictions were noticeably poor in both cases. Further developmental work, informed by this study's findings, is proposed to improve model predictions for N2 O. Soil moisture results with the spatially distributed version appeared promising but this promise could not be objectively verified.
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Source:Geoderma, Volume 315
Author(s): Yi Liu, Yuefen Li, Paul Harris, Laura M. Cardenas, Robert M. Dunn, Hadewij Sint, Phil J. Murray, Michael R.F. Lee, Lianhai Wu
Graphical abstract
