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8 results on '"KUTSCH, WERNER"'

3. Building a Global Ecosystem Research Infrastructure to Address Global Grand Challenges for Macrosystem Ecology.

Author

Loescher, Henry W., Vargas, Rodrigo, Mirtl, Michael, Morris, Beryl, Pauw, Johan, Yu, Xiubo, Kutsch, Werner, Mabee, Paula, Tang, Jianwu, Ruddell, Benjamin L., Pulsifer, Peter, Bäck, Jaana, Zacharias, Steffen, Grant, Mark, Feig, Gregor, Zhang, Leiming, Waldmann, Christoph, and Genazzio, Melissa A.

Subjects
GREEN infrastructure, SCIENTIFIC community, ECOSYSTEMS, ENVIRONMENTAL infrastructure, BIOMES
Abstract

The development of several large‐, "continental"‐scale ecosystem research infrastructures over recent decades has provided a unique opportunity in the history of ecological science. The Global Ecosystem Research Infrastructure (GERI) is an integrated network of analogous, but independent, site‐based ecosystem research infrastructures (ERI) dedicated to better understand the function and change of indicator ecosystems across global biomes. Bringing together these ERIs, harmonizing their respective data and reducing uncertainties enables broader cross‐continental ecological research. It will also enhance the research community capabilities to address current and anticipate future global scale ecological challenges. Moreover, increasing the international capabilities of these ERIs goes beyond their original design intent, and is an unexpected added value of these large national investments. Here, we identify specific global grand challenge areas and research trends to advance the ecological frontiers across continents that can be addressed through the federation of these cross‐continental‐scale ERIs. Plain Language Summary: The development of several large‐, "continental"‐scale ecosystem research infrastructures over recent decades has provided a unique opportunity in the history of ecological science. By bringing together these research infrastructures and harmonizing their respective data will more broadly enable cross‐continental ecological research. It will also improve the capabilities of the research community to anticipate and address future global scale ecological challenges to the planet. Moreover, increasing the international capabilities of these research infrastructures goes beyond their original design intent, and is an unexpected added value of these large national investments. Here, we identify specific global grand challenge areas and research trends to advance the ecological frontiers across continents that can be addressed through the federation of these cross‐continental‐scale ecosystem research infrastructures. Key Points: For the first time in history, we are able to bring together continental‐scale Ecosystem Research Infrastructures globallyThis effort enables macrosystem ecologists to ask research questions from continent‐to‐continent in ways not available beforeThis effort provides baseline data to tackle current and future unknown ecological challenges that society will face [ABSTRACT FROM AUTHOR]

Published
2022
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4. Fluxes of total reactive atmospheric nitrogen (Sigma N-r) using eddy covariance above arable land

Author

Bruemmer, Christian, Marx, Oliver, Kutsch, Werner, Ammann, Christof, Wolff, Veronika, Flechard, Christophe, Freibauer, Annette, Thunen Inst Climate Smart Agr TI AK, Thunen Institute of Climate-Smart Agriculture, LI COR Biosci GmbH, Agroscope, Sol Agro et hydrosystème Spatialisation (SAS), Institut National de la Recherche Agronomique (INRA)-AGROCAMPUS OUEST, EU project NitroEurope-IP [017841], EC 6th Framework Program for Research and Technological Development, Max Planck Institute for Biogeochemistry (MPI-BGC) in Jena, Germany, AGROCAMPUS OUEST, and Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut National de la Recherche Agronomique (INRA)

Subjects
OILSEED RAPE, CARBON FLUXES, total reactive nitrogen (Sigma N-r) exchange, NITRIC-OXIDE, [SDV]Life Sciences [q-bio], ecosystem N saturation, AMMONIA FLUXES, Agricultural land, biosphere-atmosphere exchange, Converter, Ecosystem N saturation, Eddy covariance, Fertilization, N budget, TRANC, Zotal reactive nitrogen (Sigma N-r) exchange, converter, FOREST, agricultural land, DRY DEPOSITION, fertilization, GAS, ECOSYSTEMS, eddy covariance, EXCHANGE, PLANT
Abstract

The amount and timing of reactive nitrogen exchange between agricultural land and the atmosphere play a key role in evaluating ecosystem productivity and in addressing atmospheric nitrogen budgets and transport. With the recent development of the Total Reactive Atmospheric Nitrogen Converter (TRANC) apparatus, a methodology has been provided for continuous measurement of the sum of all airborne nitrogen containing species (Sigma N-r) allowing for diurnal and seasonal investigations. We present Sigma N-r concentration and net flux data from an 11-month field campaign conducted at an arable field using the TRANC system within an eddy-covariance setup. Clear diurnal patterns of both Sigma N-r concentrations and fluxes with significant dependencies on atmospheric stability and stomatal regulation were observed in the growing season. TRANC data were compared with monthly-averaged concentrations and dry deposition rates of selected N-r compounds using DELTA denuders and ensemble-averages of four inferential models, respectively. Similar seasonal trends were found for N-r concentrations from DELTA and TRANC measurements with values from the latter being considerably higher than those of DELTA denuders. The variability of the difference between these two systems could be explained by seasonally changing source locations of NOx contributions to the TRANC signal. As soil and vegetation N-r emissions to the atmosphere are generally not treated by inferential (dry deposition) models, TRANC data showed lower monthly deposition rates than those obtained from inferential modelling. Net Sigma N-r exchange was almost neutral (similar to 0.072 kg N ha(-1)) at the end of the observation period. However, during most parts of the year, slight but permanent net Sigma N-r deposition was found. Our measurements demonstrate that fertilizer addition followed by substantial Sigma N-r emissions plays a crucial role in a site's annual atmospheric nitrogen budget. As long-term N-r measurements with high temporal resolution are usually cost and labour-intensive, field application of the TRANC helps improve the understanding of ecosystem functioning, atmospheric transport and revising definitions of ecosystem-specific critical loads at a relatively moderate operational cost level.

Published
2013
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5. Surface-atmosphere exchange of ammonia over peatland using QCL-based eddy-covariance measurements and inferential modeling.

Author

Zöll, Undine, Brümmer, Christian, Schrader, Frederik, Ammann, Christof, Ibrom, Andreas, Flechard, Christophe R., Nelson, David D., Zahniser, Mark, and Kutsch, Werner L.

Subjects
AMMONIA & the environment, QUANTUM cascade lasers, ECOSYSTEMS, SPECTROMETRY, CLIMATE change, PEATLANDS
Abstract

Recent advances in laser spectrometry offer new opportunities to investigate ecosystem-atmosphere exchange of environmentally relevant trace gases. In this study, we demonstrate the applicability of a quantum cascade laser (QCL) absorption spectrometer to continuously measure ammonia concentrations at high time resolution and thus to quantify the net exchange between a seminatural peatland ecosystem and the atmosphere based on the eddy-covariance approach. Changing diurnal patterns of both ammonia concentration and fluxes were found during different periods of the campaign. We observed a clear tipping point in early spring with decreasing ammonia deposition velocities and increasingly bidirectional fluxes that occurred after the switch from dormant vegetation to CO2 uptake but was triggered by a significant weather change. While several biophysical parameters such as temperature, radiation, and surface wetness were identified to partially regulate ammonia exchange at the site, the seasonal concentration pattern was clearly dominated by agricultural practices in the surrounding area. Comparing the results of a compensation point model with our measurement-based flux estimates showed considerable differences in some periods of the campaign due to overestimation of non-stomatal resistances caused by low acid ratios. The total cumulative campaign exchange of ammonia after 9 weeks, however, differed only in a 6% deviation with 911 and 857 g NH3-N ha-1 deposition being found by measurements and modeling, respectively. Extrapolating our findings to an entire year, ammonia deposition was lower than reported by Hurkuck et al. (2014) for the same site in previous years using denuder systems. This was likely due to a better representation of the emission component in the net signal of eddy-covariance fluxes as well as better adapted site-specific parameters in the model. Our study not only stresses the importance of high-quality measurements for studying and assessing land surface-atmosphere interactions but also demonstrates the potential of QCL spectrometers for continuous observation of reactive nitrogen species as important additional instruments within long-term monitoring research infrastructures such as ICOS or NEON at sites with strong nearby ammonia sources leading to relatively high mean background concentrations and fluxes. [ABSTRACT FROM AUTHOR]

Published
2016
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6. Steeper declines in forest photosynthesis than respiration explain age-driven decreases in forest growth.

Author

Jianwu Tang, Luyssaert, Sebastiaan, Richardson, Andrew D., Kutsch, Werner, and Janssens, Ivan A.

Subjects
FORESTS & forestry, PRIMARY productivity (Biology), PHOTOSYNTHESIS, BIOMES, ECOSYSTEMS
Abstract

The traditional view of forest dynamics originated by Kira and Shidei [Kira T, Shidei T (1967) Jap J Ecol 17:70-87] and Odum [Odum EP (1969) Science 164(3877):262-270] suggests a decline in net primary productivity (NPP) in aging forests due to stabilized gross primary productivity (GPP) and continuously increased autotrophic respiration (Ra). The validity of these trends in GPP and Ra is, however, very difficult to test because of the lack of long-term ecosystem-scale field observations of both GPP and Ra. Ryan and colleagues [Ryan MG, Binkley D, Fownes JH (1997) Ad Ecol Res 27:213-262] have proposed an alternative hypothesis drawn from site-specific results that aboveground respiration and below-ground allocation decreased in aging forests. Here, we analyzed data from a recently assembled global database of carbon fluxes and show that the classical view of the mechanisms underlying the age-driven decline in forest NPP is incorrect and thus support Ryan's alternative hypothesis. Our results substantiate the agedriven decline in NPP, but in contrast to the traditional view, both GPP and Ra decline in aging boreal and temperate forests. We find that the decline in NPP in aging forests is primarily driven by GPP, which decreases more rapidly with increasing age than Ra does, but the ratio of NPP/GPP remains approximately constant within a biome. Our analytical models describing forest succession suggest that dynamic forest ecosystem models that follow the traditional paradigm need to be revisited. [ABSTRACT FROM AUTHOR]

Published
2014
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8. Phenology and gross primary production of two dominant savanna woodland ecosystems in Southern Africa.

Author

Jin, Cui, Xiao, Xiangming, Merbold, Lutz, Arneth, Almut, Veenendaal, Elmar, and Kutsch, Werner L.

Subjects
*PHENOLOGY, *PRIMARY productivity (Biology), *SAVANNA ecology, *FORESTS & forestry, *ECOSYSTEMS, *REMOTE sensing, *CARBON cycle
Abstract

Abstract: Accurate estimation of gross primary production (GPP) of savanna woodlands is needed for evaluating the terrestrial carbon cycle at various spatial and temporal scales. The eddy covariance (EC) technique provides continuous measurements of net CO2 exchange (NEE) between terrestrial ecosystems and the atmosphere. Only a few flux tower sites were run in Africa and very limited observational data of savanna woodlands in Africa are available. Although several publications have reported on the seasonal dynamics and interannual variation of GPP of savanna vegetation through partitioning the measured NEE data, current knowledge about GPP and phenology of savanna ecosystems is still limited. This study focused on two savanna woodland flux tower sites in Botswana and Zambia, representing two dominant savanna woodlands (mopane and miombo) and climate patterns (semi-arid and semi-humid) in Southern Africa. Phenology of these savanna woodlands was delineated from three vegetation indices derived from Moderate Resolution Imaging Spectroradiometer (MODIS) and GPP estimated from eddy covariance measurements at flux tower sites (GPPEC). The Vegetation Photosynthesis Model (VPM), which is driven by satellite images and meteorological data, was also evaluated, and the results showed that the VPM-based GPP estimates (GPPVPM) were able to track the seasonal dynamics of GPPEC. The total GPPVPM and GPPEC within the plant growing season defined by a water-related vegetation index differed within the range of ±6%. This study suggests that the VPM is a valuable tool for estimating GPP of semi-arid and semi-humid savanna woodland ecosystems in Southern Africa. [Copyright &y& Elsevier]

Published
2013
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