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@ARTICLE{Frank:190231,
author = {Frank, D. C. and Poulter, B. and Saurer, M. and Esper, J.
and Huntingford, C. and Helle, G. and Treydte, K. and
Zimmermann, N. E. and Schleser, Gerhard, Hans and Ahlström,
A. and Ciais, P. and Friedlingstein, P. and Levis, S. and
Lomas, M. and Sitch, S. and Viovy, N. and Andreu-Hayles, L.
and Bednarz, Z. and Berninger, F. and Boettger, T. and
D‘Alessandro, C. M. and Daux, V. and Filot, M. and
Grabner, M. and Gutierrez, E. and Haupt, M. and Hilasvuori,
E. and Jungner, H. and Kalela-Brundin, M. and Krapiec, M.
and Leuenberger, M. and Loader, N. J. and Marah, H. and
Masson-Delmotte, V. and Pazdur, A. and Pawelczyk, S. and
Pierre, M. and Planells, O. and Pukiene, R. and
Reynolds-Henne, C. E. and Rinne, K. T. and Saracino, A. and
Sonninen, E. and Stievenard, M. and Switsur, V. R. and
Szczepanek, M. and Szychowska-Krapiec, E. and Todaro, L. and
Waterhouse, J. S. and Weigl, M.},
title = {{W}ater-use efficiency and transpiration across {E}uropean
forests during the {A}nthropocene},
journal = {Nature climate change},
volume = {5},
issn = {1758-6798},
address = {London},
publisher = {Nature Publ. Group},
reportid = {FZJ-2015-03151},
pages = {579–583},
year = {2015},
abstract = {The Earth’s carbon and hydrologic cycles are intimately
coupled by gas exchange through plant stomata1, 2, 3.
However, uncertainties in the magnitude4, 5, 6 and
consequences7, 8 of the physiological responses9, 10 of
plants to elevated CO2 in natural environments hinders
modelling of terrestrial water cycling and carbon storage11.
Here we use annually resolved long-term δ13C tree-ring
measurements across a European forest network to reconstruct
the physiologically driven response of intercellular CO2
(Ci) caused by atmospheric CO2 (Ca) trends. When removing
meteorological signals from the δ13C measurements, we find
that trees across Europe regulated gas exchange so that for
one ppmv atmospheric CO2 increase, Ci increased by ~0.76
ppmv, most consistent with moderate control towards a
constant Ci/Ca ratio. This response corresponds to
twentieth-century intrinsic water-use efficiency (iWUE)
increases of 14 ± 10 and 22 ± $6\%$ at broadleaf and
coniferous sites, respectively. An ensemble of process-based
global vegetation models shows similar CO2 effects on iWUE
trends. Yet, when operating these models with climate
drivers reintroduced, despite decreased stomatal opening,
$5\%$ increases in European forest transpiration are
calculated over the twentieth century. This counterintuitive
result arises from lengthened growing seasons, enhanced
evaporative demand in a warming climate, and increased leaf
area, which together oppose effects of CO2-induced stomatal
closure. Our study questions changes to the hydrological
cycle, such as reductions in transpiration and air humidity,
hypothesized to result from plant responses to anthropogenic
emissions.},
cin = {IBG-3},
ddc = {550},
cid = {I:(DE-Juel1)IBG-3-20101118},
pnm = {255 - Terrestrial Systems: From Observation to Prediction
(POF3-255) / 255 - Terrestrial Systems: From Observation to
Prediction (POF3-255)},
pid = {G:(DE-HGF)POF3-255 / G:(DE-HGF)POF3-255},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000356814800036},
doi = {10.1038/nclimate2614},
url = {https://juser.fz-juelich.de/record/190231},
}
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