The project aims at achieving a better understanding of the processes that drive or limit the response of grassland systems in a world of increasing atmospheric pCO2. We will test the hypothesis that the previously shown increase in below-ground allocation of C under elevated pCO2 provides the necessary energy excess and will stimulate free-living N2 fixers in a low N grassland environment. The project thus aims at assessing the occurrence and importance of free-living N2 fixers under elevated pCO2 and identify the associated microbial communities involved in order to better understand ecosystems response and sustainability of grassland systems. This project had the last opportunity to obtain soil samples from a grassland ecosystem adapted to long-term (10 year) elevated atmospheric pCO2 as the Swiss FACE experiment. The project aims to identify the relevant components of free-living diazotrophs of the microbial community using 15N stable isotope - DNA probing.
Recent events such as the Pakistan earthquake, Hurricane Katrina, the Indian Ocean tsunami and the European heat waves of 2003 reveal the vulnerability of societies to extreme events. The goal of this project is to strengthen prevention, mitigation and preparedness strategies in order to reduce the health, social and economic impacts of extreme events on communities. The objectives of the MICRODIS project are to strengthen the scientific and empirical foundation on the relationship between extreme events and their impacts; to develop and integrate knowledge, concepts, methods and databases towards a common global approach and to improve human resources and coping capacity in Asia and Europe through training and knowledge sharing. This integrated project involves 19 partners from Asia and Europe, including research, policy and ground roots institutions. The outputs will include an evidence-base on impacts, field methodologies and tools for data compilation, impact models, and integrated vulnerability assessments. It will also strengthen standardised data collection of extreme events and their impacts at local, regional and global levels. Prime Contractor: Université Catholique de Louvain; Louvain-la-neuve; Belgium.
The HyFLEET:CUTE project involves the operation of 47 hydrogen powered buses in regular public transport service in 10 cities on three continents. The Project aims to diversify and reduce energy consumption in the transport system by developing new, fuel efficient hydrogen powered bus technology, and clean, efficient and safe ways of producing and distributing hydrogen fuel. Objectives: - Develop hydrogen powered bus technology in order to reduce the consumption of fuel and energy in the whole transportation system. - Develop efficient and environmentally 'friendly' ways to produce hydrogen. - Research the technology and development needs to establish a hydrogen refueling infrastructure. - Inform the community and key decision-makers about the potential advantages of a hydrogen-based transport system and how they can help to develop it.
Aquifers are the main source of water in most semi-arid areas of the Mediterranean basin. As a result of over-exploitation hydrologic deficits of varying acuity prevail in these areas. Seawater intrusion and pollution have been identified as the primary factors for quality degradation. Further deterioration can be expected based on trends in the precipitation regime attributed to climate change. The objective of this project is to identify alternative sources of water and to investigate the feasibility, both environmental and economic of their utilization. Alternative water sources to be artificially recharged comprise: surface water runoff, treated effluent, and imported water. Furthermore, brackish water bodies, present in many aquifers could be utilised after desalination. The project structured into eight work-packages comprehensively addresses all issues related to the problem: expected precipitation rates, recharge and water budgets, identification of potential alternative water sources and technologies for their utilization, development of tools for the management of groundwater resources under artificial recharge conditions, aquifer vulnerability assessment, characterization of the unsaturated zone, and mixing effects. Four test sites have been selected for practical application of the approach. Substantial field testing, integration of technologies and findings to ensure optimal implementations of aquifer recharge alternatives, quantification of socio-economic impacts and development of dissemination platform are planned. Finally a carefully designed project management shall drive and accompany the project execution in order to ascertain consistency and efficiency.
The objectives of the REMAP project are to work with key stakeholders in order to achieve the following objectives: Compilation of a solar and wind energy resource atlas for the Southern and Eastern Mediterranean area. Identifying and prioritising potential demonstration sites for wind and concentrated solar projects in Algeria, Tunisia, Jordan and Turkey. Recording a set of commitments to be made by major stakeholders to push forward a few wind and concentrated solar thermal energy projects in the region. Proposing a credible financing scheme for the identified priority renewable demonstration projects in the region. Elaborating an action plan for a few well identified initiatives able to be implemented. Disseminating the results of the project to as wide an audience in Europe and the Mediterranean region as possible. The REMAP project team is uniquely qualified to achieve these objectives representing all major geographic, sectoral and stakeholder areas necessary to achieve these targets. The team is multidisciplinary, covering sociological, local and national policy, scientific, technology development, investment and energy deployment disciplines in the region concerned by this project. Hence, the project represents the partners own objectives, and covers various aspects of work they are engaged in or wish to engage in to promote renewable energy development and investment in the Mediterranean region. The partners, who represent each of the stakeholder groups identified by the REMAP consortium belong to a wide range of European and international networks from which they can draw considerable support and experience, on the one hand, and into which they can disseminate the results of the project, and promote its approaches, methodologies and frameworks, on the other. Dissemination and promotion of results are essential to help achieve Community and neighbouring state targets, and are two of the key objectives of the project.
Objective: New process route for lightweight, unbreakable and economically feasible solar panels on the basis of amorphous silicon. Results: From a number of canditates enamel-coated steel sheet as substrate and an organic barrier as protective layer was chosen as an alternative to the dual glass panels. Criteria were vacuum compatibility, surface rougness and insulating properties. This concept requires that the production order of the thin film solar cell is reversed into back electrode, active stack, front transparent electrode. Inverted processes and low temperature processes were investigated in parallel. Protection against damage due to permeating water was reduced with an improved organic barrier coating. Also, less vulnerable back electrode materials were studied. Fluorine doped tin oxide, tin-doped indiumoxide and aluminium-doped zinc oxide were studied. However, the best and most economical results were optained with ITO. For monolithic integration mechanical masking and laser scribing were investigated. Mechanical masking failed due to the uneveness of the enamel surface. Laser scribing is possible due to the diminished power need with each consecutive layer. Some concepts for better light capture (texturing, optical coatings) were investigated. Based on the inverted process route small scale and full scale panels were manufactured and tested. Ultimately, the full scale failed due to the built-up of stress which caused delamination and could not sufficiently be reduced. The panel costs of the new route proved very similar to the existing product, but required an additional investment in vacuum deposition equipment. Surprisingly, ITO with recycling proved to be the most cost effective transparent electrode material.
This GSE-FM service option provides a powerful tool for effective forest monitoring and inventory at regional scale using both EO-data and ground based observations. It is especially designed for allocating reliable and up-to-date information over large forest areas. Many regions of the world like wide parts of Russia and the Irkutsk Oblast are covered by vast forests. The countries and administrative regions often have to deal with pressing environmental problems such as frequent forest fires events, illegal logging practices as well as other human activities and natural forest disturbances. Due to the large forest areas, which are often difficult to access or characterized by insufficient infrastructure and severe climate conditions, frequent monitoring of the forest resources is a great challenge. Forest monitoring by the means of ground inventories is rather complicated or even impossible. The use of aerial photographs is also often insufficient and cost-intensive. As a result, forest information available today, often does not correspond to the current situation. This is true for wide parts of Siberia, for example. However, according to their own legislation and to fulfill international obligations up-to-date and reliable information on forest resources are essential. For instance, in order to update the Russian State Forest Account as well as for forest management and monitoring issues an annual update of forest information is obligatory. The use of EO-technologies offers an excellent tool to obtain spatial forest information. Especially for regions covered by vast forest areas the combined use of high and low resolution EO-data is the most promising and cost-efficient strategy. Therefore, this GSE-FM service option follows a two-level strategy: Level 1: Low and medium resolution satellite data are used for operational monitoring of forest changes over large areas caused by fires, cutting, and other natural and human induced disturbances. Territories where significant changes occurred are identified at this level. Level 2: Both high-resolution satellite data and aerial photos are used for a detailed inventory of all candidates registered by the first level observations. Ground truth data (inventory maps, topography, archive EO data etc.) are used in addition.
Under the 2003 EU Greek presidency, cooperation with Balkan countries on environmental issues was identified as a priority of the EU/Balkan Action Plan. Large-scale co-operation is essential for effective action in the vulnerable Mediterranean and Black Sea coastal zones. During the last 50 years both areas suffered major changes; as semi-enclosed basins, both Seas are ultra-sensitive to anthropogenic stress and to climate change. An EU Presidency Conference on Sustainable Development in the Mediterranean/Black Sea (May 2003), revealed major gaps in management structures, scientific strategies and identified a diversity of environmental issues to be resolved through priority-focused RTD cooperation. Yet, while pressure on the resources of the two seas increases and the potential impact of climate change on coastal and deep-sea resources remains unknown, the two seas have never been jointly studied as systems of interacting basins and ecosystems. The proposal outlines collaboration and clustering schemes involving environmental, economic and scientific organisations in Mediterranean, Black Sea and other EU nations, in order to create synergies in networking and exchanges at several levels, addressing for the first time the system of interconnected basins as one, based on the integration of, both horizontally and vertically, natural scientists and economists. These will: 1) Create an international, interdisciplinary platform coordinating the region's scientific potential in order to prepare RTD projects, based on a Science Plan for the region, securing sustainable development; 2) Focus on natural and anthropogenic pressures exerted upon the functioning of the ecosystem; 3) Reinforce RTD capacity by setting up an environment/resource monitoring network in the light of existing observation networks of different scopes. Prime Contractor: Hellenic Centre for Marine Research, Institute of Oceanography, Anavyssos, GR.
Intention of the study is to compare conventional systems for flow control in combined sewer systems with control systems based on fuzzy logic. The objective of both control strategies is to reduce the combined sewer overflow volume by an optimization of the utilized storage capacities of combined sewer overflow tanks. Conventional real time control of flow in urban drainage systems based on rules is in common use. The Effluent of combined overflow basins, for example, can be adjusted as a function of the water level in the storage tank. Additionally, the hydraulic conditions at other significant points in a sewer system or at the waste water treatment plant can be considered. Therefore, control systems are based on a large number of rules. Instead of conventional control systems it is possible to use control strategies based on fuzzy logic. Fuzzy control combines the simple rules of an expert system with a flexible specification of output parameters. Especially for the control of complex sewer systems, demanding an extensive matrix of different rules, it can be favourable to use fuzzy control. Fuzzy control enables to integrate available operating experiences in an intelligible rule base and avoids abrupt changes of the controlled parameters. In waste water treatment fuzzy control was successfully implemented to improve treatment processes during operation. The possibility to integrate operating experiences of technical staff into the rule base of a fuzzy controller and the flexible reaction of fuzzy logic on dif-ferent combinations of input parameters, led to positive results. So far, fuzzy control has only rarely been used for flow control in sewer systems. ITWH Hannover tested the application of fuzzy control for two differently structured combined sewer systems in order to minimize the storm water overflow volume. The comparison of the studies were solely based on the simulation of uncontrolled and fuzzy - controlled sewer systems for single storm events. In both cases the overflow volume could be re-duced significantly by the use of fuzzy control. The interest of the studies was focused on the initial state in comparison with the state affected by fuzzy control. The objective of the investigation reported here, has been the comparison of a conventional rule based flow control with a fuzzy based flow control. In spite of a similar rule base fuzzy control obviously enables a more flexible sizing of the outflow. The use of fuzzy logic to control several basins in a complex sewer systems helps to avoid sudden and intense changes of the controlled effluents. This leads to steady and proportionate conditions and reduces the overflow volume. In the combined sewer system investigated, a conventional rule based and a fuzzy logic system is generated to control three combined sewer overflow tanks. The control process intends a better utilization of storage capacity to reduce overflow volume
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