37 research outputs found

    Nitrogen mineralization and gaseous nitrogen losses from waterlogged and drained organic soils in a black alder (<i>Alnus glutinosa</i> (L.) Gaertn.) forest

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    Black alder (<i>Alnus glutinosa</i> (L.) Gaertn.) forests on peat soils have been reported to be hotspots for high nitrous oxide (N<sub>2</sub>O) losses. High emissions may be attributed to alternating water tables of peatlands and to the incorporation of high amounts of easily decomposable nitrogen (N) into the ecosystem by symbiotic dinitrogen (N<sub>2</sub>)-fixation of alder trees. Our study addressed the question to what extent drainage enhances the emissions of N<sub>2</sub>O from black alder forests and how N turnover processes and physical factors influence the production of N<sub>2</sub>O and total denitrification. The study was conducted in a drained black alder forest with variable groundwater tables at a southern German fen peatland. Fluxes of N<sub>2</sub>O were measured using the closed chamber method at two drained sites (D-1 and D-2) and one undrained site (U). Inorganic N contents and net N mineralization rates (NNM) were determined. Additionally a laboratory incubation experiment was carried out to investigate greenhouse gas and N<sub>2</sub> fluxes at different temperature and soil moisture conditions. Significantly different inorganic N contents and NNM rates were observed, which however did not result in significantly different N<sub>2</sub>O fluxes in the field but did in the laboratory experiment. N<sub>2</sub>O fluxes measured were low for all sites, with total annual emissions of 0.51 ± 0.07 (U), 0.97 ± 0.13 (D-1) and 0.93 ± 0.08 kg N<sub>2</sub>O–N ha<sup>−1</sup> yr<sup>&minus;1</sup> (D-2). Only 37% of the spatiotemporal variation in field N<sub>2</sub>O fluxes could be explained by peat temperature and groundwater level, demonstrating the complex interlinking of the controlling factors for N<sub>2</sub>O emissions. However, temperature was one of the key variables of N<sub>2</sub>O fluxes in the incubation experiment conducted. Increasing soil moisture content was found to enhance total denitrification losses during the incubation experiment, whereas N<sub>2</sub>O fluxes remained constant. At the undrained site, permanently high groundwater level was found to prevent net nitrification, resulting in a limitation of available nitrate (NO<sub>3</sub><sup>&minus;</sup>) and negligible gaseous N losses. N<sub>2</sub>O flux rates that were up to four times higher were measured in the incubation experiment. They reveal the potential of high N<sub>2</sub>O losses under changing soil physical conditions at the drained alder sites. The high net nitrification rates observed and high NO<sub>3</sub><sup>&minus;</sup> contents bear the risk of considerable NO<sub>3</sub><sup>&minus;</sup> leaching at the drained sites

    CO2 fluxes and ecosystem dynamics at five European treeless peatlands – merging data and process oriented modeling

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    The carbon dioxide (CO2) exchange of five different peatland systems across Europe with a wide gradient in land use intensity, water table depth, soil fertility and climate was simulated with the process oriented CoupModel. The aim of the study was to find out whether CO2 fluxes, measured at different sites, can be explained by common processes and parameters or to what extend a site specific configuration is needed. The model was calibrated to fit measured CO2 fluxes, soil temperature, snow depth and leaf area index (LAI) and resulting differences in model parameters were analyzed. Finding site independent model parameters would mean that differences in the measured fluxes could be explained solely by model input data: water table, meteorological data, management and soil inventory data. Seasonal variability in the major fluxes was well captured, when a site independent configuration was utilized for most of the parameters. Parameters that differed between sites included the rate of soil organic decomposition, photosynthetic efficiency, and regulation of the mobile carbon (C) pool from senescence to shooting in the next year. The largest difference between sites was the rate coefficient for heterotrophic respiration. Setting it to a common value would lead to underestimation of mean total respiration by a factor of 2.8 up to an overestimation by a factor of 4. Despite testing a wide range of different responses to soil water and temperature, rate coefficients for heterotrophic respiration were consistently the lowest on formerly drained sites and the highest on the managed sites. Substrate decomposability, pH and vegetation characteristics are possible explanations for the differences in decomposition rates. Specific parameter values for the timing of plant shooting and senescence, the photosynthesis response to temperature, litter fall and plant respiration rates, leaf morphology and allocation fractions of new assimilates, were not needed, even though the gradient in site latitude ranged from 48° N (southern Germany) to 68° N (northern Finland) differed largely in their vegetation. This was also true for common parameters defining the moisture and temperature response for decomposition, leading to the conclusion that a site specific interpretation of these processes is not necessary. In contrast, the rate of soil organic decomposition, photosynthetic efficiency, and the regulation of the mobile carbon pool need to be estimated from available information on specific soil conditions, vegetation and management of the ecosystems, to be able to describe CO2 fluxes under different condition

    Forest tree growth is linked to mycorrhizal fungal composition and function across Europe

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    Most trees form symbioses with ectomycorrhizal fungi (EMF) which influence access to growth-limiting soil resources. Mesocosm experiments repeatedly show that EMF species differentially affect plant development, yet whether these effects ripple up to influence the growth of entire forests remains unknown. Here we tested the effects of EMF composition and functional genes relative to variation in well-known drivers of tree growth by combining paired molecular EMF surveys with high-resolution forest inventory data across 15 European countries. We show that EMF composition was linked to a three-fold difference in tree growth rate even when controlling for the primary abiotic drivers of tree growth. Fast tree growth was associated with EMF communities harboring high inorganic but low organic nitrogen acquisition gene proportions and EMF which form contact versus medium-distance fringe exploration types. These findings suggest that EMF composition is a strong bio-indicator of underlying drivers of tree growth and/or that variation of forest EMF communities causes differences in tree growth. While it may be too early to assign causality or directionality, our study is one of the first to link fine-scale variation within a key component of the forest microbiome to ecosystem functioning at a continental scale

    Klimarelevanz von Mooren und Anmooren in Deutschland: Ergebnisse aus dem Verbundprojekt "Organische Böden in der Emissionsberichterstattung"

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    [Projektziel] Ziel des Projekts war es, deutschlandweit aktuelle Daten zu FlÀchen organischer Böden, Nutzung, WasserstÀnden und Treibhausgasemissionen zu erheben und somit die aktuelle Treibhausgasbilanz der organischen Böden in Deutschland zu quantifizieren

    Treibhausgasemissionen aus organischen Böden im deutschen Treibhausgasinventar: Methodenentwicklung und Ergebnisse

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    EntwĂ€sserte organische Böden sind in vielen LĂ€ndern, darunter auch in Deutschland, eine starke Quelle anthropogener Treibhausgase (THG). Daher mĂŒssen sie bei der Berichterstattung gemĂ€ĂŸ UNFCCC und Kyoto-Protokoll angemessen berĂŒcksichtigt werden. Hier beschreiben wir die Methodik, Daten und Ergebnisse der deutschen detaillierten Tier-3-Methodik zur Berichterstattung anthropogener Treibhausgasemissionen aus entwĂ€sserten organischen Böden, die fĂŒr das deutsche Treibhausgasinventar entwickelt und angewandt wurden. Der Ansatz basiert auf nationalen Daten und bietet das Potenzial, Änderungen der Landnutzung und des Wassermanagements zu verfolgen, falls Zeitreihen zu relevanten AktivitĂ€tsdaten vorliegen. Die AktivitĂ€tsdaten umfassen hochauflösende Karten zu Klima, Landnutzung, organischen Böden und vom mittleren jĂ€hrlichen Grundwasserflurabstand. Die Grundwasserkarte wurde durch ein statistisches Modell aus Daten von &gt; 1000 Standorten abgeleitet. Die THG-Emissionen beruhen auf einem einzigartigen Datensatz mit mehr als 200 THG-Bilanzen fĂŒr fast alle Kombinationen von Landnutzungskategorien und Typen organischer Böden. Die Messungen wurden mit vollstĂ€ndig harmonisierten Protokollen durchgefĂŒhrt. Nicht-lineare Funktionen beschreiben die AbhĂ€ngigkeit der Kohlendioxid- und Methan-FlĂŒsse vom mittleren jĂ€hrlichen Grundwasserstand und, wenn erforderlich, von der Landnutzung. Die daraus resultierenden "angewandten Emissionsfaktoren" fĂŒr jede Landnutzungskategorie berĂŒcksichtigen sowohl die Unsicherheit der nicht-linearen Funktionen als auch die Verteilung der GrundwasserstĂ€nde in jeder Landnutzungskategorie. Da keine einfachen funktionellen ZusammenhĂ€nge fĂŒr die Lachgasemissionen gefunden wurden, wurden die entsprechenden Emissionsfaktoren daher als Mittelwerte der Messwerte jeder Landnutzungskategorie berechnet. FĂŒr kleinere THG-Quellen wie Methanemissionen aus GrĂ€ben und AustrĂ€ge von gelöstem organischem Kohlenstoff wurden IPCC-Standard-Emissionsfaktoren verwendet
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