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@ARTICLE{Schafer:111953,
author = {Schafer, K. and Böttcher, J. and Weymann, D. and von der
Heide, C and Duijnisveld, W.H.M.},
title = {{E}valuation of a {C}losed {T}unnel for {F}ield-{S}cale
{M}easurements of {N}itrous {O}xide {F}luxes from an
{U}nfertilized {G}rassland {S}oil},
journal = {Journal of environmental quality},
volume = {41},
issn = {0047-2425},
address = {Madison, Wis.},
publisher = {ASA [u.a.]},
reportid = {PreJuSER-111953},
pages = {1383 - 1392},
year = {2012},
note = {This study was funded by German Research Foundation (DFG).
The authors thank Helmut Geistlinger, Danny Eisermann,
Carsten Jahn, Michael Wiwiorra, Christoph Bonecke,
Nils-Demian Landmeyer, and Joris Fahle for the effective
cooperation; Markus Deurer, Heinz Flessa, Reinhard Well,
Stefan Emeis, Klaus Butterbach-Bahl, Hans Papen, Peter
Suppan, Hans Peter Schmid, and Richard Grant for valuable
discussions; Theresa A. Norris for language editing; and two
anonymous reviewers for their constructive comments and
valuable recommendations that helped to improve a previous
version of the manuscript.},
abstract = {Emissions of the major greenhouse gas NO from soils are
characterized by huge spatial variability. An upscaling
based on conventional small-scale chamber measurements is
thus questionable and may involve a considerable amount of
uncertainty. In this feasibility study, we evaluated the
applicability of a large, closed tunnel for field-scale
measurements of NO fluxes from an unfertilized grassland
soil. The tunnel, coupled to an open-path Fourier transform
infrared spectrometer, covered 500 m. During a 2-yr
campaign, concurrent closed-chamber measurements (area of
0.045 m) were performed at the tunnel plot. The tunnel
system enabled high-density and precise NO concentration
measurements under dry, stable, nocturnal atmospheric
conditions, but higher wind speeds and rain limited its
application. To calculate an unbiased, predeployment NO flux
from the increase of NO concentrations during tunnel
deployment, we propose a novel approach based on inverse
modeling (IMQ0). We show that IMQ0 is appropriate for the
specific non-steady state tunnel setup. Compared with
conventional models, which were developed for gas flux
calculation from concentration gradients measured in vented
closed chambers, IMQ0 is most accurate. Whereas NO fluxes
obtained from the tunnel measurements were generally small
and at a typical background level, the chamber measurements
revealed high spatial and temporal variability of NO
emissions, including slight NO uptake and
precipitation-triggered emission peaks. The cumulative NO
fluxes of both methods differed by one order of magnitude
and were smaller for the tunnel measurements. We argue that
the chambers were occasionally susceptible to detection of
hotspots and hot moments of NO emission. However, these
emissions were evidently not representative for the field
scale. Compared with available greenhouse gas measurement
techniques, we conclude that the tunnel may serve as a
gap-filling method between small-scale chamber and
ecosystem-level micrometeorological techniques, particularly
during stable nocturnal conditions.},
keywords = {J (WoSType)},
cin = {IBG-3},
ddc = {333.7},
cid = {I:(DE-Juel1)IBG-3-20101118},
pnm = {Terrestrische Umwelt},
pid = {G:(DE-Juel1)FUEK407},
shelfmark = {Environmental Sciences},
typ = {PUB:(DE-HGF)16},
pubmed = {pmid:23099929},
UT = {WOS:000308931700004},
doi = {10.2134/jeq2011.0475},
url = {https://juser.fz-juelich.de/record/111953},
}
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