Das Projekt "The long-term landscape evolution of the Lambert Rift - An integrated thermochronological approach" wird vom Umweltbundesamt gefördert und von Universität Bremen, Fachbereich 5 Geowissenschaften durchgeführt.
Das Projekt "Fixed Point Open Ocean Observatories Network (FIXO3)" wird vom Umweltbundesamt gefördert und von Natural Environment Research Council durchgeführt. The Fixed point Open Ocean Observatory network (FixO3) seeks to integrate European open ocean fixed point observatories and to improve access to these key installations for the broader community. These will provide multidisciplinary observations in all parts of the oceans from the air-sea interface to the deep seafloor. Coordinated by the National Oceanography Centre, UK, FixO3 will build on the significant advances achieved through the FP7 programmes EuroSITES, ESONET and CARBOOCEAN. With a budget of 7.00 Million Euros over 4 years (starting September 2013) the proposal has 29 partners drawn from academia, research institutions and SMEs. In addition 14 international experts from a wide range of disciplines comprise an Advisory Board. The programme will be achieved through: 1. Coordination activities to integrate and harmonise the current procedures and processes. Strong links will be fostered with the wider community across academia, industry, policy and the general public through outreach, knowledge exchange and training. 2. Support actions to offer a) access to observatory infrastructures to those who do not have such access, and b) free and open data services and products. 3. Joint research activities to innovate and enhance the current capability for multidisciplinary in situ ocean observation. Open ocean observation is currently a high priority for European marine and maritime activities. FixO3 will provide important data on environmental products and services to address the Marine Strategy Framework Directive and in support of the EU Integrated Maritime Policy. The FixO3 network will provide free and open access to in situ fixed point data of the highest quality. It will provide a strong integrated framework of open ocean facilities in the Atlantic from the Arctic to the Antarctic and throughout the Mediterranean, enabling an integrated, regional and multidisciplinary approach to understand natural and anthropogenic change in the ocean.
Das Projekt "Permafrost Carbon Cycle Observations and Modeling across multiple spatiotemporal scales (PERCCOM)" wird vom Umweltbundesamt gefördert und von Max-Planck-Institut für Biogeochemie durchgeführt. Permafrost ecosystems in the high Northern latitudes are estimated to store about 1700 Petagram of carbon, which is roughly 50% of the total global belowground carbon, or about double the amount currently contained in the global atmosphere. Future climate projections indicate a strong warming potential for these regions over the next century, which may significantly alter the biogeochemical processes governing the carbon cycle, and thus holds the potential to partly destabilize and release these enormous existing carbon reservoirs. At the same time, the database on carbon exchange fluxes between surface and atmosphere is sparse compared to the size of the region, and significant gaps exist concerning e.g. the coverage of specific landscape units, or observations during the cold season. As a consequence, many processes within the permafrost carbon cycle remain poorly understood, leading to large uncertainties in climate model simulations for this region. To close existing gaps in both flux Arctic flux databases and process understanding, integrated monitoring and modeling tools are required that provide insight into feedback mechanisms between permafrost ecosystems and climate change. This project will establish year-round observation systems in the permafrost region that integrate over multiple spatiotemporal scales to capture carbon flux variability from local to continental levels. The obtained information will be used to identify causal links between environmental drivers and patterns in carbon fluxes based on an integrated framework of atmospheric transport modeling, multivariate statistics, geostatistical inversion and biogeochemical process modeling. The resulting insights into biogeochemical mechanisms will help to improve process representation in modeling frameworks, with the overarching objective to reduce uncertainties in climate projections.
Das Projekt "Energy and Water Fluxes at the Soil Atmosphere Interface of Water Repellent soils" wird vom Umweltbundesamt gefördert und von Technische Universität Berlin, Institut für Ökologie, Fachgebiet Bodenkunde durchgeführt. Water repellency (WR) plays a significant role in a large number of soils all over the world. In many regions global warming will lead to drier land surfaces and thus, increasing the likeliness of actual water repellency for such soils. The hydrological effects of WR (surface runoff, water erosion, preferential flow) have been relatively well investigated in the last decades. However, its effect on the energy balance between soil and atmosphere has not been studied yet. We postulate that global warming does not only lead to an increase in WR of soils, but WR has an impact on the energy balance and thus, will lead to a feedback on global warming. In order to test our hypothesis, we want to determine all components of the energy- and water balance between soil and atmosphere for a strongly water repellent soil. As a reference we want to repeat the same measurements for the same soil, at which the WR has been suspended by application of a surfactants. While the laboratory studies aim to give insight into more principle processes, the lysimeter (bare and with plants) and field scale studies shall give information about integrated complex natural processes. The gained knowledge shall be implemented into a numerical simulation tool for modeling water and energy balances in order to predict the effects of WR under different atmospheric conditions and physical soil properties.
Das Projekt "Biopolymers from syngas fermentation (SYNPOL)" wird vom Umweltbundesamt gefördert und von Agencia estatal consejo superior de investigaciones cientificas durchgeführt. SYNPOL aims to propel the sustainable production of new biopolymers from feedstock. SYNPOL will theretoestablish a platform that integrates biopolymer production through modern processing technologies, withbacterial fermentation of syngas, and the pyrolysis of highly complex biowaste (e.g., municipal, commercial,sludge, agricultural). The R&D activities will focus on the integration of innovative physico-chemical, biochemical,downstream and synthetic technologies to produce a wide range of new biopolymers. The integration will engagenovel and mutually synergistic production methods as well as the assessment of the environmental benefitsand drawbacks. This integrative platform will be revolutionary in its implementation of novel microwave pyrolytictreatments together with systems-biology defined highly efficient and physiologically balanced recombinantbacteria. The latter will produce biopolymer building-blocks and polyhydroxyalkanoates that will serve tosynthesize novel bio-based plastic prototypes by chemical and enzymatic catalysis. Thus, the SYNPOL platformwill empower the treatment and recycling of complex biological and chemical wastes and raw materials in asingle integrated process. The knowledge generated through this innovative biotechnological approach will notonly benefit the environmental management of terrestrial wastes, but also reduce the harmful environmentalimpact of petrochemical plastics. This project offers a timely strategic action that will enable the EU to lead worldwide the syngas fermentation technology for waste revalorisation and sustainable biopolymer production.
Das Projekt "Wood2Chem: a computer aided platform to support the optimal implementation of wood-based bio refinery concepts" wird vom Umweltbundesamt gefördert und von Ecole Polytechnique Federale de Lausanne, Institut de Thermique, Laboratoire d'Energetique Industrielle durchgeführt. Wood2CHem: A computer-aided platform for developing bio-refinery concepts The bio-refinery concept offers the timber industry numerous development opportunities by integrating the production of value-added products made from biomass. The computer-aided platform Wood2CHem, developed within the scope of this project, will help to devise innovative means for promoting wood as a resource using a holistic and integrated approach. Background Due to its composition and complex chemical structure, wood can be used to make a large number of value-added products. The bio-refinery concept proposes to widen the range of products derived from wood while adopting a systemic approach aimed at promoting synergies in the production of various products by integrating different processes. It therefore offers an enormous development potential for the wood sector and opens up many new markets. The development of bio-refinery concepts poses a significant challenge. A large number of processes that integrate studies and technologies of innovative transformation need to be evaluated, integrated and optimised using a holistic approach before the most promising concepts can be identified. Aim By applying techniques from process engineering, energy integration and multi-objective optimisation, the consortium of the Wood2CHem project proposes to develop a computer-aided platform for systematically generating the most promising bio-refinery models and evaluating their thermodynamic, economic and environmental performance. This integrated platform will be developed by combining expertise in chemical engineering and process engineering. It is aimed at integrating technological developments of wood transformation and will be validated in industrial case studies. Significance The Wood2CHem project concerns the development of industrial concepts and will therefore primarily interest experts and engineers in the field who wish to develop integrated and innovative concepts for a rational promotion of wood. It will allow them to envisage and compare inegrated process chains. The platform will integrate all the actors wishing to assume the perspective of industrial ecology.
Das Projekt "Quantifying and modelling pathways of soil organic matter as affected by abiotic factors, microbial dynamics, and transport processes (QUASOM)" wird vom Umweltbundesamt gefördert und von Max-Planck-Institut für Biogeochemie durchgeführt. Soils play a critical role in the coupled carbon-cycle climate system. However, our scientific understanding of the role of soil biological-physicochemical interactions and of vertical transport for biogeochemical cycles is still limited. Moreover the representation of soil processes in current models operating at global scale is crude compared to vegetation processes like photosynthesis. Hence, the general aim of this project is to improve our understanding of the key interactions between the biological and the physicochemical soil systems that are often not explicitly considered in current experimental and modeling approaches and are likely to influence the biogeochemical cycles for a large part of the terrestrial biosphere and thus have the potential to significantly impact the Earth System as a whole. This will be achieved through an approach that integrates new soil mesocosm experiments, field data from ongoing European projects and soil process modeling. In mesocosm tracer experiments the fate of fresh and autochthonous soil organic matter will be followed under varying temperature and moisture regimes in bacterial and fungal dominated soils and the hypothesis tested that transfer coefficients between soil organic matter pools are constant as implemented in current soil organic matter models. A new soil model structure will be developed that may explicitly account for the role of microbes and transport for soil organic matter dynamics. This will be supported by multiple-constraint model identification techniques, which allows testing and achieving model consistency with several observation types. An incorporation of such new soil module into a global dynamic vegetation model (DGVM) is foreseen.
Das Projekt "Selective tribological optimisation of fluid kinetics and efficiency by laser surface structuring (STOKES)" wird vom Umweltbundesamt gefördert und von Fraunhofer-Institut für Produktionstechnologie durchgeführt. Economic losings caused by wear and friction are still tremendous, just in Germany the losings are amounted to 100 bn € p.a., for Europe the losses exceed 400 bn €. Recent investigations have shown that laser manufactured structures can exert considerable influence on the tribological behaviour of surfaces. Besides hydrodynamic effects, which can improve friction, the ability of the structures to store lubricant lead to the maintenance of a lubrication film. As the state of the art techniques for laser surface structuring, particularly for tribological applications are mainly on an a R&D level, the production technology is in need of adequate manufacturing techniques. Main topics in this field of research are the inevitable pre- and post-treatment steps of current laser surface structuring techniques as well as the high process durations. The overall goal of this project is to solve both of those tasks by the development and realisation of a process technology, which enables the process chain integrated laser surface structuring of hydraulic parts. The project aims to cover a defined segment of a growing market and the technological achievements will offer the participating SMEs promising options of upgrading their product values. In addition to the direct improvement of single systems by the investigations on demonstration parts within the project, the high transferability of the technique to further products will enable the value enhancement of whole product classes. This offers the possibility of a strong enhancement of the total product output. A consortium has been established, which covers the laser supply and technique as well as the surface preparation technology. Manufacturers of hydraulic parts are members of the consortium in order to close the technological range. Two powerful RTD performers could be gained, which are specialised on the laser processing on the one hand and on tribology on the other hand.
Das Projekt "Advancing the Integrated Monitoring of Trace Gas Exchange between Biosphere and Atmosphere (ABBA)" wird vom Umweltbundesamt gefördert und von Max-Planck-Institut für Biogeochemie durchgeführt. Descriptions are provided by the Actions directly via e-COST. The global environment is a complex system with numerous intricately linked processes. The land surface-atmosphere interface plays a vital role in the functioning of the Earth System by controlling transfers of energy, momentum and matter. Thus, land atmosphere interactions are important factors controlling and affecting the Earth climate system. To increase and evaluate our understanding of the critical controlling processes, interactions and feedbacks between biosphere and atmosphere, long-term integrated interdisciplinary monitoring efforts are necessary. This COST Action creates a platform for analysis, harmonisation, and synthesis, assessment of future needs and further development of a European integrated monitoring program for comprehensive trace gas flux observations. The existing national and European flux monitoring communities work separately; networking by this COST Action creates added value and is invaluable to advance the continuity, scope and quality of flux monitoring. This Action advances the applicability of produced data in climate and Earth system modelling research, as well as in more operational short to medium term forecasting of weather and air quality. Current methodologies, operationality, dissemination, and coordination will also be addressed in this COST Action. Development of common methodologies, data management systems and protocols will increase the reliability, value and cost-efficiency of European flux observations. Keywords: land-atmosphere interactions, energy and biogeochemical fluxes, multi-species flux monitoring, assimilation in climate and weather forecasting models, climate and global change
Das Projekt "Water in industry, fit-for-use sustainable water use in chemical, paper, textile and food industry (AQUAFIT4USE)" wird vom Umweltbundesamt gefördert und von Nederlandse Centrale Organisatie voor Toegepast-Natuurwetenschappelijk Onderzoek durchgeführt. Objective: Sustainable water use in industry is the goal of AquaFit4Use, by a cross-sectorial, integrated approach. The overall objectives are: the development and implementation of new, reliable, cost-effective technologies, tools and methods for sustainable water supply, use and discharge in the main water consuming industries in order to significantly reduce water use, mitigate environmental impact and produce and apply water qualities in accordance with industrial own specifications (fit - for - use) from all possible sources, and contributing to a far-going closure of the water cycle in a economical, sustainable and safe way while improving their product quality and process stability. The 4 pillars of the project are Industrial Water Fit-for-use, Integrated water resource management, Strong industrial participation and Cross-sectorial technologies and approach. Water fit-for-use is the basis for sustainable water use; the integrated approach a must. Tools will be developed to define and control water quality. The heart of AquaFit4Use however is the development of new cross-sectorial technologies, with a focus at biofouling and scaling prevention, the treatment of saline streams, disinfection and the removal of specific substances. By intensive co-operation between the industries, the knowledge and the technologies developed in this project will be broadly transferred and implemented. This AquaFit4Use project is based on the work of the Working group 'Water in Industry' of the EU Water Platform WSSTP; 40 Prozent of the project partners of AquaFit4Use were involved in this working group. The expected impacts of AquaFit4Use are: A substantial reduction of fresh water needs (20 to 60Prozent) and effluent discharge of industries; Integrating process technologies for further closing the water cycles; Improved process stability and product quality in the different sectors and strengthening the competitiveness of the European Water Industry.'
