Abstract
Abstract. Many hydrological models including root water uptake (RWU) do not consider the dimension of root system hydraulic architecture (HA) because explicitly solving water flow in such a complex system is too time consuming. However, they might lack process understanding when basing RWU and plant water stress predictions on functions of variables such as the root length density distribution. On the basis of analytical solutions of water flow in a simple HA, we developed an "implicit" model of the root system HA for simulation of RWU distribution (sink term of Richards' equation) and plant water stress in three-dimensional soil water flow models. The new model has three macroscopic parameters defined at the soil element scale, or at the plant scale, rather than for each segment of the root system architecture: the standard sink fraction distribution SSF, the root system equivalent conductance Krs and the compensatory RWU conductance Kcomp. It clearly decouples the process of water stress from compensatory RWU, and its structure is appropriate for hydraulic lift simulation. As compared to a model explicitly solving water flow in a realistic maize root system HA, the implicit model showed to be accurate for predicting RWU distribution and plant collar water potential, with one single set of parameters, in dissimilar water dynamics scenarios. For these scenarios, the computing time of the implicit model was a factor 28 to 214 shorter than that of the explicit one. We also provide a new expression for the effective soil water potential sensed by plants in soils with a heterogeneous water potential distribution, which emerged from the implicit model equations. With the proposed implicit model of the root system HA, new concepts are brought which open avenues towards simple and mechanistic RWU models and water stress functions operational for field scale water dynamics simulation.
Highlights
Plants impact the terrestrial water cycle, in particular, through evapotranspiration
The validity of the implicit model for realistic root systems relies on three hypotheses: (i) the equations developed with the simple hydraulic architecture (HA) apply for more complex root system HA, (ii) root axial resistances to water flow values are low enough to neglect their effect on compensatory root water uptake (RWU), (iii) all the root nodes located within a certain soil element have a soil-root interface water potential which can be approximated by the averaged water potential of the soil nodes of the soil element
It is notable that all the shown standard sink fraction distribution (SSF) differ from the relative root length density vector
Summary
Plants impact the terrestrial water cycle, in particular, through evapotranspiration. Even though hydrological and climate models are sensitive to RWU and plant water stress parameters (Desborough, 1997; Zeng et al, 1998), no consensus exists on the modelling of these two processes (Feddes et al, 2001; Skaggs et al, 2006; Raats, 2007). From a conceptual point of view, two main approaches exist today, which differ in the way they predict the volumetric rate of RWU, or “sink term”, of Richards’ equation in volume elements of soil: ∂θ. Note that the units of K and Hs differ from standards of soil physics, but were chosen for consistency with those used in plant physiology
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