Um Herausforderungen im Bereich Energiepflanzenanbau zu begegnen wird das Zweikulturnutzungssystem als innovative Anbaumethode erforscht und auf Demonstrationsflächen in zwei Landkreisen exemplarisch umgesetzt.
Die Roadmap of Change bietet Strategien, Prinzipien und Handlungsempfehlungen, um die Metropolregion Bremen-Oldenburg im Nordwesten auf die Folgen des Klimawandels vorzubereiten. Bis zum Jahr 2050 soll die Region nicht nur an die zu erwartenden Klimaveränderungen angepasst, sondern insgesamt resilienter gegenüber Störereignissen sein. Wie diese Roadmap entsteht und was sie beinhaltet, erläutert diese Ausgabe von „kurz+bündig“.
Der Bericht "Bereitstellung des regional angepassten Entscheidungshilfesystems LandCaRe-DSS" repräsentiert das REGKLAM-Produkt 3.3.1g. Das Entscheidungshilfesystem LandCaRe-DSS (Land, Climate and Resources Decision Support System) ist eine modellbasierte Wissensplattform, die die explizite Simulation von regionalen und lokalen Auswirkungen des Klimawandels anhand von regionalen Klimaprojektionen ermöglicht. Damit soll das Wissen um mögliche Klimafolgen ergänzt und die Ableitung von Anpassungsmaßnahmen in der Landwirtschaft unterstützt werden. Ziel des Teilprojektes (TP3.3.1g) war die Übertragung des Systems auf die Modellregion Dresden.
Die „Auricher Erklärung“ enthält die Ergebnisse und die Dokumentation einer Tagung von 'nordwest2050', die im Februar 2013 stattgefunden hat und auf der über die vielfältigen Flächenansprüche im Nordwesten diskutiert wurde. Mehr als 100 Vertreterinnen und Vertreter aus Landwirtschaft, Verbänden, Kammern, Naturschutzorganisationen, Verwaltung, Politik und Wissenschaft tauschten sich in sechs Workshops zum Thema Flächenkonkurrenzen aus. Die "Auricher Erklärung" soll als Ausgangspunkt für einen öffentlichen Dialog dienen, der die Endlichkeit der Ressource Fläche anerkennt und den behutsamen Umgang damit in den Mittelpunkt stellt.
Abstract
Water management and environmental protection is vulnerable to extreme low flows during streamflow droughts. During the last decades, in most rivers of Central Europe summer runoff and low flows have decreased. Discharge projections agree that future decrease in runoff is likely for catchments in Brandenburg, Germany. Depending on the first-order controls on low flows, different adaption measures are expected to be appropriate. Small catchments were analyzed because they are expected to be more vulnerable to a changing climate than larger rivers. They are mainly headwater catchments with smaller ground water storage. Local characteristics are more important at this scale and can increase vulnerability.
This thesis mutually evaluates potential adaption measures to sustain minimum runoff in small catchments of Brandenburg, Germany, and similarities of these catchments regarding low flows. The following guiding questions are addressed: (i) Which first-order controls on low flows and related time scales exist? (ii) Which are the differences between small catchments regarding low flow vulnerability? (iii) Which adaption measures to sustain minimum runoff in small catchments of Brandenburg are appropriate considering regional low flow patterns?
Potential adaption measures to sustain minimum runoff during periods of low flows can be classified into three categories: (i) increase of groundwater recharge and subsequent baseflow by land use change, land management and artificial ground water recharge, (ii) increase of water storage with regulated outflow by reservoirs, lakes and wetland water management and (iii) regional low flow patterns have to be considered during planning of measures with multiple purposes (urban water management, waste water recycling and inter-basin water transfer). The question remained whether water management of areas with shallow groundwater tables can efficiently sustain minimum runoff. Exemplary, water management scenarios of a ditch irrigated area were evaluated using the model Hydrus-2D. Increasing antecedent water levels and stopping ditch irrigation during periods of low flows increased fluxes from the pasture to the stream, but storage was depleted faster during the summer months due to higher evapotranspiration. Fluxes from this approx. 1 km long pasture with an area of approx. 13 ha ranged from 0.3 to 0.7 ls-1 depending on scenario. This demonstrates that numerous of such small decentralized measures are necessary to sustain minimum runoff in meso-scale catchments.
Differences in the low flow risk of catchments and meteorological low flow predictors were analyzed. A principal component analysis was applied on daily discharge of 37 catchments between 1991 and 2006. Flows decreased more in Southeast Brandenburg according to meteorological forcing. Low flow risk was highest in a region east of Berlin because of intersection of a more continental climate and the specific geohydrology. In these catchments, flows decreased faster during summer and the low flow period was prolonged. A non-linear support vector machine regression was applied to iteratively select meteorological predictors for annual 30-day minimum runoff in 16 catchments between 1965 and 2006. The potential evapotranspiration sum of the previous 48 months was the most important predictor (r2 = 0.28). The potential evapotranspiration of the previous 3 months and the precipitation of the previous 3 months and last year increased model performance (r2 = 0.49, including all four predictors). Model performance was higher for catchments with low yield and more damped runoff. In catchments with high low flow risk, explanatory power of long term potential evapotranspiration was high.
Catchments with a high low flow risk as well as catchments with a considerable decrease in flows in southeast Brandenburg have the highest demand for adaption. Measures increasing groundwater recharge are to be preferred. Catchments with high low flow risk showed relatively deep and decreasing groundwater heads allowing increased groundwater recharge at recharge areas with higher altitude away from the streams. Low flows are expected to stay low or decrease even further because long term potential evapotranspiration was the most important low flow predictor and is projected to increase during climate change. Differences in low flow risk and runoff dynamics between catchments have to be considered for management and planning of measures which do not only have the task to sustain minimum runoff.
Der Bericht beschreibt die Aktivitäten des Projekts RADOST in den fünf Modulen „Netzwerk und Dialog“, „Natur- und ingenieurwissenschaftliche Forschung“, „Sozio-ökonomische Analyse“, „Nationaler und europäischer Politikrahmen/ nationaler und internationaler Austausch“ und „Kommunikation und Verbreitung der Ergebnisse“ und deckt den Zeitraum von April 2012 bis Januar 2013 ab.