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@BOOK{Bechtold:136391,
author = {Bechtold, Michel},
title = {{E}xperimental and numerical studies on solute transport in
unsaturated heterogeneous porous media under evaporation
conditions},
volume = {143},
school = {Universität Bonn},
type = {Dr.},
address = {Jülich},
publisher = {Forschungszentrum Jülich GmbH Zentralbibliothek, Verlag},
reportid = {PreJuSER-136391},
isbn = {978-3-89336-795-5},
series = {Schriften des Forschungszentrums Jülich. Reihe Energie und
Umwelt / energy and environment},
pages = {XVIII, 131 S.},
year = {2012},
note = {Record converted from JUWEL: 18.07.2013; Universität Bonn,
Diss., 2012},
abstract = {Groundwater level rise, root water uptake, or evaporation
induces local upward water and solute fluxes in soils,
causing soil salinization and rise of contaminants to the
soil surface, and influencing the migration of solutes to
the groundwater. It is known that soil heterogeneity
strongly controls transport under infiltration conditions,
but its effect on transport under upward flow conditions has
barely been investigated. In this thesis, laboratory tracer
experiments were conducted in artificial porous media with
known heterogeneity under evaporation conditions and
observations were compared with numerical simulations in
order to improve the understanding of upward flow and
transport processes. High concentration gradients due to
solute accumulation at the soil surface caused by
evaporation are posing very high demands on Eulerian schemes
for solving the advection-dispersion equation (ADE), while
they have no negative effect on the stability of random walk
particle tracking (RWPT) schemes. However, RWPT loses
accuracy when the dispersion tensor or the water content is
spatially discontinuous, a topic that is frequently-debated
in RWPT literature. In this thesis, a new RWPT algorithm is
presented that builds on the former concept of representing
the discontinuities by partially reflecting barriers. Three
improvements were developed that enhance the accuracy and
efficiency of this concept by orders of magnitude. In a
composite porous medium, consisting of a cylindrical inner
core with coarse sand that was surrounded by fine sand, dye
and salt tracer experiments were conducted under constant
evaporation conditions, and a Gd-DTPA$^{2}$- tracer
experiment was monitored with magnetic resonance imaging
(MRI) during a cycle of infiltration and evaporation. The
key finding of these experiments was the formation of high
solute concentration spots at the surface of the coarse
material, which is contrary to the general expectation that
solutes accumulate and precipitate in regions with finer
texture and higher evaporation fluxes. Flow and transport
simulations showed that molecular diffusion, which moves
solutes away from the evaporating surface back into the
porous medium, in combination with lateral water flow
redistributes solutes towards locations with the lowest
hydraulic head. The formation of high solute concentration
spots at the surface of coarser regions, which usually
represent preferential flow pathways during strong
precipitation, may have an accelerating effect on the
leaching of solutes. [...]},
cin = {IBG-3},
ddc = {500},
cid = {I:(DE-Juel1)IBG-3-20101118},
typ = {PUB:(DE-HGF)3},
url = {https://juser.fz-juelich.de/record/136391},
}
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