630 Landwirtschaft und verwandte Bereiche
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Vegetation responds to drought through a complex interplay of plant hydraulic mechanisms, posing challenges for model development and parameterization. We present a mathematical model that describes the dynamics of leaf water-potential over time while considering different strategies by which plant species regulate their water-potentials. The model has two parameters: the parameter λ describing the adjustment of the leaf water potential to changes in soil water potential, and the parameter Δψww describing the typical ‘well-watered’ leaf water potentials at non-stressed (near-zero) levels of soil water potential. Our model was tested and calibrated on 110 time-series datasets containing the leaf- and soil water potentials of 66 species under drought and non-drought conditions. Our model successfully reproduces the measured leaf water potentials over time based on three different regulation strategies under drought. We found that three parameter sets derived from the measurement data reproduced the dynamics of 53% of an drought dataset, and 52% of a control dataset [root mean square error (RMSE) < 0.5 MPa)]. We conclude that, instead of quantifying water-potential-regulation of different plant species by complex modeling approaches, a small set of parameters may be sufficient to describe the water potential regulation behavior for large-scale modeling. Thus, our approach paves the way for a parsimonious representation of the full spectrum of plant hydraulic responses to drought in dynamic vegetation models.
Within the world’s oceans, regionally distinct ecological niches develop due to differences in water temperature, nutrients, food availability, predation and light intensity. This results in differences in the vertical dispersion of planktonic foraminifera on the global scale. Understanding the controls on these modern-day distributions is important when using these organisms for paleoceanographic reconstructions. As such, this study constrains modern depth habitats for the northern equatorial Indian Ocean, for 14 planktonic foraminiferal species (G. ruber, G. elongatus, G. pyramidalis, G. rubescens, T. sacculifer, G. siphonifera, G. glutinata, N. dutertrei, G. bulloides, G. ungulata, P. obliquiloculata, G. menardii, G. hexagonus, G. scitula) using stable isotopic signatures (δ18O and δ13C) and Mg/Ca ratios. We evaluate two aspects of inferred depth habitats: (1) the significance of the apparent calcification depth (ACD) calculation method/equations and (2) regional species-specific ACD controls. Through a comparison with five global, (sub)tropical studies we found the choice of applied equation and δ18Osw significant and an important consideration when comparing with the published literature. The ACDs of the surface mixed layer and thermocline species show a tight clustering between 73–109 m water depth coinciding with the deep chlorophyll maximum (DCM). Furthermore, the ACDs for the sub-thermocline species are positioned relative to secondary peaks in the local primary production. We surmise that food source plays a key role in the relative living depths for the majority of the investigated planktonic foraminifera within this oligotrophic environment of the Maldives and elsewhere in the tropical oceans.
The Global Irrigation Model (GIM) is used within the framework of the global hydrological model WaterGAP to calculate monthly irrigation crop water use. Results on a 0.5 degrees grid include, consumption (ICU) and, via division by irrigation efficiencies, water withdrawal (IWU). The model distinguishes up to two cropping periods of rice and non-rice crops, each grown for 150 days, using a grid of area equipped for irrigation (AEI). Historical development of AEI and fraction of area actually irrigated (AAI) was previously considered via scaling of cell-specific results with country-specific factors for each year. In this study, GIM was adapted to use the new Historical Irrigation Data set (HID) with cell-specific AEI for 14 time slices between 1900 and 2005. AEI grids were temporally interpolated, and using the optional grid of AAI/AEI, results for years 1901-2014 were generated (runs "HID-ACT"). Thus, new installation or abandonment of irrigation infrastructure in new grid cells can be represented in a spatially explicit manner. For evaluated years 1910, 1960, 1995, and 2005, ICU from HID-ACT was superior to country-specific scaled results (run "HID-ACTHIST") in representing historical development of the spatial pattern. Compared to US state-level reference data, spatial patterns were better, while country totals were not always better. For calculating the cropping periods, 30-years climate means are needed, the choice of which is relevant. Four chosen periods before 1981-2010 all resulted in considerable, pertaining changes of ICU spatial pattern, and various percent changes in country totals. This might be because of already present climate change.
This study presents a global scale analysis of cropping intensity, crop duration and fallow land extent computed by using the global dataset on monthly irrigated and rainfed crop areas MIRCA2000. MIRCA2000 was mainly derived from census data and crop calendars from literature. Global cropland extent was 16 million km2 around the year 2000 of which 4.4 million km2 (28%) was fallow, resulting in an average cropping intensity of 0.82 for total cropland extent and of 1.13 when excluding fallow land. The lowest cropping intensities related to total cropland extent were found for Southern Africa (0.45), Central America (0.49) and Middle Africa (0.54), while highest cropping intensities were computed for Eastern Asia (1.04) and Southern Asia (1.0). In remote or arid regions where shifting cultivation is practiced, fallow periods last 3–10 years or even longer. In contrast, crops are harvested two or more times per year in highly populated, often irrigated tropical or subtropical lowlands where multi-cropping systems are common. This indicates that intensification of agricultural land use is a strategy that may be able to significantly improve global food security. There exist large uncertainties regarding extent of cropland, harvested crop area and therefore cropping intensity at larger scales. Satellite imagery and remote sensing techniques provide opportunities for decreasing these uncertainties and to improve the MIRCA2000 inventory.
Obwohl Böden unzweifelhaft ein signifikanter Pool von organischem Kohlenstoff sind, ist ihre Bedeutung als potenzielle langfristige Senke für atmosphärischen Kohlenstoff keineswegs klar. Trotz bedeutender wissenschaftlicher Forschritte aus den letzten Jahren zur Klärung der Kohlenstoffdynamik in Böden gibt es nach wie vor offene Fragen insbesondere hinsichtlich der spezifischen geochemischen Mechanismen, die für die Stabilisierung organischen Kohlenstoffs in Böden verantwortlich sind. Vor diesem Hintergrund besteht ein wesentliches Ziel der vorliegenden Dissertation darin, in unterschiedlichen Bodentypen die Konzentration von organischem Kohlenstoff und Stickstoff sowie die mineralogische Zusammensetzung zu untersuchen, um Hinweise auf einen möglichen Einfluss der Tonmineralogie, der spezifischen Oberfläche und der Oxidkonzentration auf die Stabilisierung organischen Materials zu ermitteln. Die Ergebnisse sollen einen Beitrag dazu liefern, die Mechanismen der Fixierung organischer Substanz in Böden besser zu verstehen und das vorhandene Wissen hierüber zu erweitern. Hierzu wurden fünf verschiedene Bodenprofile aus Hessen mit unterschiedlicher mineralogischer Zusammensetzung untersucht. Um die Auswirkungen verschiedener physikalischer und geochemischer Faktoren auf den Gehalt organischer Substanz in den untersuchten Böden festzustellen, wurden folgende Parameter untersucht: -Tonmineralogie, -organische Kohlenstoff- und Stickstoff-Konzentrationen, -%-Kationensättigung, -spezifische Oberfläche, -dithionit- und oxalatlösliche Gehalte an Fe, Al und Mn. Anhand dieser Parameter wurden weiterführende statistische Analysen unter Verwendung der Statistiksoftware SPSS für Windows durchgeführt, um mögliche statistische Zusammenhänge aufzudecken, die für die Stabilisierung von organischem Kohlenstoff in den betrachteten Böden verantwortlich sind. Die im Rahmen der vorliegenden Dissertation ermittelten Ergebnisse zeigen, dass der Tonanteil und die Tonmineralogie der untersuchten Böden nur einen begrenzten Einfluss auf die Stabilisierung organischer Substanz haben. Weiterhin wird gezeigt, dass die in der Literatur propagierte Beziehung zwischen spezifischer Oberfläche und der Konzentration organischen Kohlenstoffs nicht auf alle Böden anwendbar ist. Die Ergebnisse deuten darauf hin, dass die Präsenz von amorphen Eisen- und Aluminiumoxiden der wichtigste Einflussfaktor für die Fixierung von organischem Material in den untersuchten Böden ist. Die größeren Konzentrationen von organischem Kohlenstoff in den kleinsten Fraktionen (Feinschluff und Ton) der Profile sind vor allem darauf zurückzuführen, dass Oxide ebenfalls in diesen Fraktionen aufzufinden sind. Tonminerale haben demnach eine sekundäre Bedeutung, indem sie Komplexe mit den Oxiden bilden, die zur Stabilisierung von organischer Substanz führen können. Insgesamt deuten die Ergebnisse daraufhin, dass Böden keine geeignete Senke für die langfristige Speicherung von organischem Kohlenstoff sind. Obwohl Mechanismen wie die Adsorption von organischer Substanz an Oxide die Stabilisierung organischen Materials unterstützen, scheinen diese nicht stark genug zu sein, um eine permanente Speicherung von organischem Kohlenstoff zu bewirken.