Die Gesamtfilterwirkung ist ein Kennwert zur Bewertung des Bodens als Filter für sorbierbare Stoffe und wird über das mechanische und physiko-chemische Filtervermögen bewertet. Unter sorbierbare Stoffe fallen insbesondere Stoffgruppen wie die Kationen der Nährstoffe, Schwermetalle und Organika, die entweder im Bodenwasser gelöst sind oder an kleinen Partikeln haften bzw. selbst in Partikelform vorliegen. In gelöster Form werden die genannten Stoffe an den Austauschern (Bodenmaterial) gebunden und so der Bodenlösung entzogen. In Partikelform werden sie im Boden gefiltert, wenn sie aufgrund mechanischer Hindernisse, wie z. B. am Ende von Wurmröhren, mit dem Sickerwasser nicht mehr weiter transportiert werden können. Die Gesamtfilterwirkung kann in Abhängigkeit von der Kationenaustauschkapazität und der Luftkapazität geschätzt werden. Das Schätzergebnis besteht aus insgesamt 11 Stufen, von denen in Schleswig-Holstein nur 8 relevant sind. Je höher die Stufe ist, desto höher ist die Gesamtfilterwirkung. Sie ist in feinkörnigem Bodenmaterial mit geringer Luftkapazität am größten, wie z. B. in der Marsch und im Östlichen Hügelland, und in grobkörnigem Bodenmaterial mit hoher Luftkapazität am geringsten, wie z. B. in der Vorgeest. Mit der Gesamtfilterwirkung wird eine natürliche Bodenfunktionen nach § 2 Abs. 2 BBodSchG bewertet und zwar nach Punkt 1.c) als Abbau-, Ausgleichs- und Aufbaumedium für stoffliche Einwirkungen auf Grund der Filter-, Puffer- und Stoffumwandlungseigenschaften, insbesondere auch zum Schutz des Grundwassers. Das hierfür gewählte Kriterium ist das mechanische und physiko-chemische Filtervermögen des Bodens mit dem Kennwert Gesamtfilterwirkung. Die Karten liegen für die folgenden Maßstabsebenen vor: - 1 : 1.000 - 10.000 für hochaufgelöste oder parzellenscharfe Planung, - 1 : 10.001 - 35.000 für Planungen auf Gemeindeebene, - 1 : 35.001 - 100.000 für Planungen in größeren Regionen, - 1 : 100.001 - 350.000 für landesweit differenzierte Planung, - 1 : 350.001 - 1000.000 für landesweite bis bundesweite Planung.
Das Projekt "WiSSCy: Impact of Wind, Rain, and Surface Slicks on Air-Sea CO2 Transfer Velocity - Tank Experiments" wird vom Umweltbundesamt gefördert und von Universität Hamburg, Zentrum für Meeres- und Klimaforschung, Institut für Meereskunde (IfM) durchgeführt. The goal is to improve the understanding of the parameterization of air-sea gas exchange with emphasis on CO2. This is being done using the linear wind-wave tank facility of the University of Hamburg. Using this facility, gas exchange coefficients are inferred by measuring gas transfer under a wide variety of parameters such as wind, mechanically generated waves, rain, and surface films. Our emphasis is on the physical processes involved in the air-sea gas exchange and its quantitative measurement. Experiments are conducted with freshwater and with salt water to test the influence of salinity on the gas exchange parameters. All experiments are being performed for evasion and invasion to investigate if rain-induced gas transfer is symmetrical or asymmetrical. While these experiments do not address in great detail the small-scale processes that are involved in the transfer, they allow to determine parameterizations of the gas exchange as a function of parameters of the atmospheric boundary layers as they are needed in climate models and for the analysis of satellite data.
Das Projekt "Improved Methods for the Assessment of the Generic Impact of Noise in the Environment (IMAGINE)" wird vom Umweltbundesamt gefördert und von Müller-BBM Gesellschaft mit beschränkter Haftung durchgeführt. For the production of strategic noise maps as required under the EU Directive 2002/49/EC, improved assessment methods for environmental noise will be required. Noise from any major source, be it major roads, railways, airports or industrial activities in agglomerations, needs to be included in the noise mapping. For road and rail, improved methods will be developed in the 5th frame work Harmonoise project. These methods will be adopted to develop methods for aircraft and industrial noise in the IMAGINE project proposed here. Noise source databases to be developed in IMAGINE for road and rail sources will allow a quick and easy implementation of the methods in all member states. Measured noise levels can add to the quality of noise maps because they tend to have better credibility than computed levels. In the project proposed here, guidelines for monitoring and measuring noise levels will be developed, that can contribute to a combined product (measurement and computation) that has high quality and high credibility. Noise action plans shall be based on strategic noise maps. The IMAGINE project will develop guidelines for noise mapping that will make it easy and straightforward to assess the efficiency of such action plans. Traffic flow management will be a key element of such action plans, both on a national and a regional level. Noise mapping will be developed into a dynamic process rather than a static presentation of the situation. IMAGINE will provide the link between Harmonoise and the practical process of producing noise maps and action plans. It will establish a platform where experts and end users can exchange their experience and views. This platform should continue after the project and provide a basis for exploitation to the IMAGINE results. me Contractor: Detalrail B.V.; Utrecht; Netherlands.
Das Projekt "Impact of silviculture on species diversity in forests in Germany" wird vom Umweltbundesamt gefördert und von Universität Hamburg, Arbeitsbereich für Weltforstwirtschaft und Institut für Weltforstwirtschaft des Friedrich-Löffler-Institut, Bundesforschungsinstitut für Tiergesundheit durchgeführt. Objectives: Focus of investigations is in development of species and ecosystem diversity (alpha-, beta- and gamma-diversity) as well as on ecological and population biological processes on landscape and ecosystem levels. The project asks questions on the function of forest management and landscape units for dispersal and establishment of typical forest plants (herb, shrub and tree layer), in particular on the exchange of diaspores (dispersal units) and the recolonization of biocoenologically impoverished, partly fragmented forest ecosystems. We will also check to what extent species or species groups and habitat structures can be used as indicators for monitoring of biological diversity in forests on landscape level. Major questions are: (1) How to maintain or re-create a biological diversity that is typical and as large as possible for the respective forest ecosystem? (2) What spacious effects does forest management have for the biological diversity at landscape level? (3) Which role do wild animals (e.g. hoofed game, birds) play in the diaspore dispersal of vascular forest plants? (4) How can the biological diversity be monitored with simple methods? Results: - The comparison of the recent and the ancient forest cover shows in total an increasing forest area of 636 ha. On the soils of the ground and terminal moraines deforestation exceeds by far the reforestation (balance -544ha). On the sander the afforestation of former heathland, communal pasture and fields increases the forest area round about 1.198 ha. - The rare vascular plant species, selected on the basis of their frequency in the distribution atlas of the flora of Schleswig-Holstein, are mainly found on the nutrient rich and moist sites of the recent moraine, especially in the Alno-Ulmion and the Hordelymo-Fagetum. - A comparison of the presence of the rare vascular plant species with informations in the distribution atlas leads to the presumption of a decrease of the occurence of a lot of these species. The reasons for this are discussed. - The strict relationship of the rare forest vascular plant species to sites with continously forest cover is remarkable. Only 12 of the 72 sites with at least one rare plant species are clearly afforestated agricultaral area. - Hoofed game species transport numerous plant species - partially in large amounts - over relatively long distances, both by the faeces after gut passage (endozoochory) and by adhesion to the coats and hooves (epizoochory). Especially wild boar are of particular importance, as they may potentially disperse almost plant species.
Das Projekt "SAFIRA - Abstracts of the Workshop of November 17-18, 1999 at Bitterfeld / Germany" wird vom Umweltbundesamt gefördert und von Umweltforschungszentrum Leipzig-Halle, Projektbereich Industrie- und Bergbaufolgelandschaften durchgeführt. The SAFIRA project (Sanierungsforschung in regional kontaminierten Aquiferen) focuses an the development of reactive walls for the treatment of regional contaminated aquifers. The project is managed by UFZ (Umweltforschungszentrum Leipzig-Halle) and the University of Tübingen. Within the SAFIRA project, different research groups are investigating a number of different technologies at an underground test site in Bitterfeld. Among them is a consortium from the Netherlands, lead by TNO (Netherlands Organisation for Applied Scientific Research), with Tebodin, HBG/HWZ and Shell as partners. The Dutch research project is supported by NOBIS (Netherlands Research Programme for Biological in situ Remediation). Fall 1999, the SAFIRA programme at Bitterfeld had come at an interesting point. The test site had been officially opened, most results of the on-site mobile test unit had been obtained and the in-situ reactors had been started up. On November 17-18, 1999, UFZ and TNO jointly organised a workshop at the test site in Bitterfeld. The Workshop was attended by about 50 representatives from the different research groups involved in SAFIRA, NOBIS representatives and members of the Knowledge Exchange Group related to the Dutch research project. The workshop focused on: - the methods applied; - the results obtained so far; - practical, large scale solutions for the regional groundwater problem. This report presents the workshop programme, the abstracts of the presentations and a selection of the slides that were used within the brainstorm session. We do hope that the workshop and this report will be followed-up by a further and fruitful knowledge exchange between all parties involved and that this may contribute to finding innovative, optimal solutions for the regional groundwater problems in Bitterfeld and other areas.
Das Projekt "Meridional Overturning Exchange with the Nordic Seas (MOEN) - WP4: Modelling" wird vom Umweltbundesamt gefördert und von Universität Hamburg, Zentrum für Meeres- und Klimaforschung, Institut für Meereskunde (IfM) durchgeführt. Backgrond: The mild climate of north western Europe is, to a large extent, governed by the influx of warm Atlantic water to the Nordic Seas. Model simulations predict that this influx and the return of flow of cold deep water to the Atlantic may weaken as a consequence of global warming. MOEN will assess the effect of anthropogenic climate change on the Meridional Overturning Circulation by monitoring the flux exchanges between the North Atlantic and the Nordic Seas and by assessing its present and past variability in relation to the atmospheric and thermohaline forcing. This information will be used to improve predictions of regional and global climate changes. MOEN is a self-contained project of the intercontinental Arctic-Subarctic Ocean Flux (ASOF) Array for European Climate project, which aims at monitoring and understanding the oceanic fluxes of heat, salt and freshwater at high northern latitudes and their effect on global ocean circulation and climate. MOEN will contribute to a better long-term observing system to monitor the exchanges between the North Atlantic and the Nordic Seas from direct and continuous measurements in order to allow an assessment of the effect of anthropogenic climate change on the Meridional Overturning Circulation. This we will be done by measuring and modelling fluxes and characteristics of total Atlantic inflow to the Nordic Seas and of the Iceland-Scotland component of the overflow from the Nordic Seas to the Atlantic. General objectives: To contribute to a better long-term observing system to monitor the exchanges between the North Atlantic and the Nordic Seas. To assess the effect of anthropogenic climate change on the Meridional Overturning Circulation. Modelling objectives (WP4, IfM): To model the flow field, the temperature and salinity distribution and the heat fluxes for an area focused on the Iceland-Faroe Ridge, the Faroe Bank and Faroe-Shetland Channel and Wyville-Thomson Ridge. To model long term variations of the locally induced and far field circulation and T/S distribution in order to understand climate variations.
Das Projekt "Processes of Vertical Exchange in Shelf Seas (PROVESS)" wird vom Umweltbundesamt gefördert und von Universität Hamburg, Zentrum für Meeres- und Klimaforschung, Institut für Meereskunde (IfM) durchgeführt. PROVESS is a joint European funded project for an interdisciplinary study of the vertical fluxes of properties through the water column and the surface and bottom boundaries based on the integrated application of new measuring techniques, new advances in turbulence theory and new models. IfM Hamburg is responsible for six tasks concerning numerical simulations of mean flow properties, turbulence and suspended matter transport. IfM's tasks in PROVESS are in detail: Physical modelling: Model development and code verification, cooperation with MUMM Management Unit of Mathemetical Models of North Sea and Scheldt Estuary), Brussels, Belgium. For this task, the existing public domain water column model GOTM (General Ocean Turbulence Model) will be extended. Model validation against existing data sets, cooperation with MUMM, Brussels, Belgium. Here some historical data sets will be simulated. These are the FLEX 1976 and the UWB Irish Sea FLY data set, both are scenarios already included into GOTM. Furthermore, the POL 1991 and North Sea data from NERC have to be simulated. Synthesis of PROVESS data with models, cooperation with close to all PROVESS partners. The northern and the southern North Sea experiments carried out during PROVESS will be simulated in detail by the numerical water column model. Modelling sediment damping of turbulence: Model development and code verification, cooperation with LHF (Laboratoire d'Hydraulique de France SA), Grenoble, France. Model validation against existing data sets, cooperation with LHF (Laboratoire d'Hydraulique de France SA), Grenoble, France. Synthesis of PROVESS data with models, cooperation with close to all PROVESS partners.
Das Projekt "Work Package II - Material processing at Haean Basin scale: The role of hyporheic exchange and the riparian zone in NO3 and DOC export from catchments" wird vom Umweltbundesamt gefördert und von Universität Bayreuth, Fachgruppe Geowissenschaften, Bayreuther Zentrum für Ökologie und Umweltforschung (BayCEER), Lehrstuhl für Hydrologie durchgeführt. The hydrogeochemical dynamics in mountainous areas of the Korean Peninsula are mainly driven by a monsoon-type climate. To examine the interplay between hydrological processes and the mobilization and subsequent transport and export of nitrate and DOC from catchments, a field study was initiated in the Haean catchment in north-eastern South Korea under highly variable hydrologic conditions. In order to identify nitrate and DOC source areas, a subcatchment (blue dragon river) within the Haean basin, which includes different types of landuses (forest, dry land farming, and rice paddies), was selected. In 2009, high frequency surface water samples were collected at several locations during summer storm events. A similar but more comprehensive sampling routine was completed in 2010. In order to investigate the groundwater level fluctuations relative to the hydraulic potentials, a piezometer transect was installed across a second order stream of the subcatchment. The results so far suggest deep groundwater seepage to the aquifer with practically no base flow contributions to the stream in the mid-elevation range of the catchment. In 2009 the focus of research was within the subcatchment, in 2010 additionally a second piezometer transect was installed at a third order stream in the lower part of the catchment (main stem of the Mandae River) where more dynamic groundwater/surface water interactions are assumed due to expected higher groundwater levels in this part of the basin. In order to investigate these interactions piezometers equipped with temperature sensors and pressure transducers were installed directly into the river bed. Based on the observed temperature time series and the hydraulic potentials the water fluxes between the groundwater and the river can be calculated using the finite-difference numerical code, VS2DH. VS2DH solves Richard s equation for variably-saturated water flow, and the advection-conduction equation for energy transport. The field data collected at the second piezometer transect suggest that the investigated river reach exhibits primarily losing surface conditions throughout most of the year. Gaining groundwater conditions at the river reach are evident after monsoonal extreme precipitation events. At the transect streambed aggradation and degradation due to bedload transport was observed. Significant erosion has been reported throughout the catchment after extreme events. Results indicate that the event-based changes in streambed elevation, is an additional control on groundwater and surface water exchange. The streambed flux reversals were found to occur in conjunction with cooler in-stream temperatures at potential GW discharge locations. The export of nitrate and DOC were found to be variable in time and strongly correlated to the hydrologic dynamics, i.e. the monsoon and pre- and post-monsoon hydrological conditions. usw.
Das Projekt "Research for Local Action towards Sustainable Human Settlements (RELAY)" wird vom Umweltbundesamt gefördert und von ICLEI - Local Goverments for Sustainability, Europasekretariat GmbH durchgeführt. The RELAy project will coordinate an international exchange between researchers with outstanding experience in the field of sustainable human settlements and local leaders, and their multipliers, for exchanging how research results can be best brought to the local level and serve for improving local policy implementation. A conference in Nanjing, China in November 2005 is planned as the core activity. The conference and its preparation will support the development of mutual understanding between researchers and local actors. It will mainly lead to designing cooperation models that are not only beneficial for researchers and local leaders but first of all for improving urban sustainable development and human settlements. The project will be an element of the EU and UN-HABITAT research initiative in support of sustainable human settlements.
Das Projekt "Workshop: Conservation Study of Settlement Areas along the banks of Ciliwung and Cipinang River" wird vom Umweltbundesamt gefördert und von Universität Karlsruhe (TH), Institut Entwerfen von Stadt und Landschaft, Lehrstuhl für Stadtquartiersplanung und Entwerfen durchgeführt. Als Ziel des Workshops galt es, nachhaltige Konzepte für informelle Siedlungen entlang der Flüsse Ciliwung und Cipinang zu entwickeln, mit besonderem Schwerpunkt auf dem Hochwasserschutz. Die Zusammenarbeit deutscher und indonesischer Lehrbeauftragter und Studenten war Kern des Workshops. Der Workshop ist Teil des Programms der 'Fachbezogenen Partnerschaft mit Hochschulen in Entwicklungsländern. Er fand während eines Arbeitsbesuches Karlsruher Professoren, wissenschaftlicher Mitarbeiter und Studenten statt. Beteiligt waren neben 35 Studenten der UKI vier Studenten aus Karlsruhe.