Project Details
Visualization and modeling of the evaporation process using representative 2D Micromodels and universal scaling laws
Applicant
Professor Dr. Helmut Geistlinger
Subject Area
Soil Sciences
Term
from 2016 to 2021
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 318157347
Evaporation is a key process controlling the soil water budget and is characterized by a complex interplay of atmospheric boundary conditions and the flow- and transport properties of the 3-phase system "solid phase - water - gas". The central objective is the experimental and theoretical investigation of the evaporation process for real soil structures using representative 2D-micromodels and network models. The 3D-pore structure is measured by micro-X-ray computer tomography (micro-CT) and mapped to the 2D-micromodel by a new topological 2D-3D transformation. The experimental results are compared with the theoretical results of an evaporation-network model, which for the first time takes into account the evaporation over the thick-film surface and the experimental pore size distribution. The 2D-micromodels have both an inner and an outer roughness as natural soils and loose rock. For the first time the thick-film flow is investigated as a function of the microstructure of the solid surface. Therefore, REV-micromodels (REV: representative elementary volume) are produced in silicon (inner roughness = 0.1 micro-m), glass (0.5) and glass ceramic (3). As a working hypothesis it is assumed that (i) different atmospheric conditions (diffusive flow, laminar flow and turbulent flow; increasing potential evaporation rate) cause different drying dynamics and that (ii) the critical water potential depends on the thick-film flow and on the thick-film-surface. Two soil types from agricultural land (Fuhrberger Feld) are investigated: (i) sandy soil (A-horizon) and (ii) medium sand (C-horizon). The pore structure is analyzed using micro-CT (maximal resolution: 5 micro-m) and methods of mathematical morphology (Minkowski functions). The micro-model experiments are carried out for both the horizontal and the vertical water flow in the range of relevant capillary numbers; (10^-7 ... 10^-4; increasing evaporation rate). The visualization experiments are carried out with two high-resolution SLR cameras (18 megapixels) and a fluorescence microscope. The Thick-film dynamics is described by the standard theory of "wetting on rough surfaces". For all experiments (i) a cluster analysis is conducted, (ii) the gravitational correlation length is calculated by universal scaling laws, and (iii) the fractal dimension of the drying/displacement front is determined. Based on a representative network model the two important parameters of the continuum theory (REV-scale) - the effective permeability and the effective diffusion coefficient - are derived. The expected results are both of fundamental interest and of great practical relevance, as they improve process understanding and consequently the predictive modeling of evaporation at REV-scale.
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