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@ARTICLE{Hrachowitz:897476,
author = {Hrachowitz, Markus and Stockinger, Michael and
Coenders-Gerrits, Miriam and van der Ent, Ruud and Bogena,
Heye and Lücke, Andreas and Stumpp, Christine},
title = {{R}eduction of vegetation-accessible water storage capacity
after deforestation affects catchment travel time
distributions and increases young water fractions in a
headwater catchment},
journal = {Hydrology and earth system sciences},
volume = {25},
number = {9},
issn = {1607-7938},
address = {Katlenburg-Lindau},
publisher = {EGU},
reportid = {FZJ-2021-03809},
pages = {4887 - 4915},
year = {2021},
abstract = {Deforestation can considerably affect transpiration
dynamics and magnitudes at the catchment scale and thereby
alter the partitioning between drainage and evaporative
water fluxes released from terrestrial hydrological systems.
However, it has so far remained problematic to directly link
reductions in transpiration to changes in the physical
properties of the system and to quantify these changes in
system properties at the catchment scale. As a consequence,
it is difficult to quantify the effect of deforestation on
parameters of catchment-scale hydrological models. This in
turn leads to substantial uncertainties in predictions of
the hydrological response after deforestation but also to a
poor understanding of how deforestation affects principal
descriptors of catchment-scale transport, such as travel
time distributions and young water fractions. The objectives
of this study in the Wüstebach experimental catchment are
therefore to provide a mechanistic explanation of why
changes in the partitioning of water fluxes can be observed
after deforestation and how this further affects the storage
and release dynamics of water. More specifically, we test
the hypotheses that (1) post-deforestation changes in water
storage dynamics and partitioning of water fluxes are
largely a direct consequence of a reduction of the
catchment-scale effective vegetation-accessible water
storage capacity in the unsaturated root zone (SU, max)
after deforestation and that (2) the deforestation-induced
reduction of SU, max affects the shape of travel time
distributions and results in shifts towards higher fractions
of young water in the stream. Simultaneously modelling
streamflow and stable water isotope dynamics using
meaningfully adjusted model parameters both for the pre- and
post-deforestation periods, respectively, a hydrological
model with an integrated tracer routine based on the concept
of storage-age selection functions is used to track fluxes
through the system and to estimate the effects of
deforestation on catchment travel time distributions and
young water fractions Fyw.It was found that deforestation
led to a significant increase in streamflow accompanied by
corresponding reductions of evaporative fluxes. This is
reflected by an increase in the runoff ratio from CR=0.55 to
0.68 in the post-deforestation period despite similar
climatic conditions. This reduction of evaporative fluxes
could be linked to a reduction of the catchment-scale water
storage volume in the unsaturated soil (SU, max) that is
within the reach of active roots and thus accessible for
vegetation transpiration from ∼258 mm in the
pre-deforestation period to ∼101 mm in the
post-deforestation period. The hydrological model,
reflecting the changes in the parameter SU, max, indicated
that in the post-deforestation period stream water was
characterized by slightly yet statistically not
significantly higher mean fractions of young water
(Fyw∼0.13) than in the pre-deforestation period
(Fyw∼0.12). In spite of these limited effects on the
overall Fyw, changes were found for wet periods, during
which post-deforestation fractions of young water increased
to values Fyw∼0.37 for individual storms. Deforestation
also caused a significantly increased sensitivity of young
water fractions to discharge under wet conditions from
dFyw/dQ=0.25to 0.36.},
cin = {IBG-3},
ddc = {550},
cid = {I:(DE-Juel1)IBG-3-20101118},
pnm = {2173 - Agro-biogeosystems: controls, feedbacks and impact
(POF4-217)},
pid = {G:(DE-HGF)POF4-2173},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000695408400002},
doi = {10.5194/hess-25-4887-2021},
url = {https://juser.fz-juelich.de/record/897476},
}
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