Abstract
The subject of this article is the dynamics of water in a soil pedostructure sample whose internal environment is subjected to a potential gradient created by the departure of water through surface evaporation. This work refers entirely to the results and conclusions of a fundamental theoretical study focused on the molecular thermodynamic equilibrium of the two aqueous phases of the soil pedostructure. The new concepts and descriptive variables of the hydro-thermodynamic equilibrium state of the soil medium, which have been established at the molecular level of the fluid phases of the pedostructure (water and air) in a previous article, are recalled here in the systemic paradigm of hydrostructural pedology. They allow access to the molecular description of water migration in the soil and go beyond the classical mono-scale description of soil water dynamics. We obtain a hydro-thermodynamic description of the soil′s pedostructure at different hydro-functional scale levels including those relating to the water molecule and its atoms. The experimental results show a perfect agreement with the theory, at the same time validating the systemic approach that was the framework.
Highlights
The problem of water transfer equations in soil dates back to the beginning of soil science
We demonstrated that these two types of water in the pedostructure are two aqueous phases in pressure equilibrium (hmi(Wmi) = hma(W)) and distinguished by their thermodynamic properties
The curves are homothetic: the total water content of the sample (Wt = (M − Ms)/Ms) corresponds to the values of the suction pressures h1 and h2 measured by the tensiometers and to the local water contents W1 and W2 that can be read on the retention curve h(W), characteristic of the sample
Summary
The problem of water transfer equations in soil dates back to the beginning of soil science. We resume here the study of the water transfer equation in the soil with a completely new approach: that of the systemic approach we recently theorized [1,2,3] from the work of Bertalanffy, initiator of the general theory of systems [4] and Le Moigne [5], author of the General System model. The application of this systemic approach applied to pedology has created a new paradigm of characterization, water modeling, and representation of the natural environment (multi-scale mapping).
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