The project's objective is to support JRC IPTS in revising the existing Ecolabel and GPP criteria of personal computers and notebook computers. The priority in this revision process is to first analyse which of the existing criteria and the supporting evidence are still valid and to identify the additional research that should be carried out. Potential additional criteria can be developed, if identified as necessary in the course of the study. The study starts with a definition of the scope; the necessarity for new or revised Ecolabel and GPP criteria is based on a market analysis and a technical analysis with research on the most significant environmental impacts during the whole life cycle of the products. This also includes the application of a consistent methodological approach regarding the hazardous substances criteria. Based on these findings, the improvement potential will be derived resulting in a proposal for a revised Ecolabel and GPP criteria set for desktop and notebook computers which will be discussed in a European stakeholder process.
The project's objective is to support JRC IPTS in revising the existing Ecolabel and GPP criteria of televisions. The priority in this revision process is to first analyse which of the existing criteria and the supporting evidence are still valid and to identify the additional research that should be carried out. Potential additional criteria can be developed, if identified as necessary in the course of the study. The study starts with a definition of the scope; the necessarity for new or revised Ecolabel and GPP criteria is based on a market analysis and a technical analysis with research on the most significant environmental impacts during the whole life cycle of the products. This also includes the application of a consistent methodological approach regarding the hazardous substances criteria. Based on these findings, the improvement potential will be derived resulting in a proposal for a revised Ecolabel and GPP criteria set for televisions which will be discussed in a European stakeholder process.
The aim of the current research is to identify regional sources and trans-boundary flow leading to the observed salinity of Lake Tiberias (LT) -also known as the Sea of Galilee or Lake Kinneret-, and its surroundings, which is considered the only natural surface fresh water reservoir of the area. The current study will include all sources of brines in the Tiberias Basin (TB) with specific emphasis of the relationship between the brines from the Ha'on and Tiberias Regions (HTR).The tasks will be achieved by a multidisciplinary approach involving: (i) numerical modelling of density-driven flow processes (i.e., coupled heat and dissolution of evaporites), (ii) hydrochemical studies, supplemented by investigations of subsurface structures.(i) Numerical modelling will be carried out by applying the commercial software FEFLOW® (WASY, GmbH) complemented with the open source code OpenGeoSys developed at the UFZ of Leipzig (Wang et al., 2009). The final goal is to build a 3D regional-scale model of density-driven flow that will result in: (1) revealing the different interactions between fresh groundwater and natural salinity sources (2) elucidate the driving mechanisms of natural brines and brackish water body's movements.(ii) Hydrochemical study will include major, minor and, if possible, rare earth elements (REE) as well as isotope studies. The samples will be analysed at the FU Berlin and UFZ Halle laboratories. Geochemical data interpretation and inverse modelling will be supported by PHREEQC. Hydrochemical field investigations will be carried out in Tiberias basin and its enclosing heights, i.e. the Golan, Eastern Galilee and northern Ajloun in order to search for indications of the presence of deep, relic saline groundwater infested by the inferred Ha'on mother-brine. The current approaches will be supplemented by seismic and statistical data analysis as well as GIS software applications for the definition of the subsurface structures. The key research challenges are: building a 3D structural model of selected regions of TB, adapting both structural and hydrochemical data to the numerical requirements of the model; calibrating the 3D regional-scale model with observational data. The results of this work are expected to establish suitable water-management strategies for the exploitation of freshwater from the lake and from the adjacent aquifers while reducing salinization processes induced by both local and regional brines.
The COMTES project has as goal to develop and demonstrate three novel systems for compact seasonal storage of solar thermal energy. These systems will contribute to the EU 20-20-20 targets by covering a larger share of the domestic energy demand with solar thermal energy. Main objective of COMTES is to develop and demonstrate systems for seasonal storage that are significantly better than water based systems. The three technologies are covered in COMTES by three parallel development lines: solid sorption, liquid sorption and supercooling PCM. Strength of this approach is the collaboration of three development groups in activities that pertain to the analyses, methods and techniques that concern all technologies, without risking the exchange of confidential material. In this way, the development is much more effective than in three separate projects. The project starts with a definition of system boundary conditions and target applications. Next comes the investigation of the best available storage materials. Detailed numerical modelling of the physical processes, backed by experimental validations, will lead to optimum component design. Full-scale prototypes are simulated, constructed and tested in the laboratory in order to optimize process design. One year of fully monitored operation in demonstration buildings is followed by an integrated evaluation of the systems and their potential. When deemed successful, the involved industry partners will pick up the developed storage concepts and bring them further to a commercial level. The COMTES project is a cooperation of key scientific institutions active in the above mentioned heat storage technologies. For the first time, all relevant research disciplines are covered in an international effort. For each development line, a top-Ieading industry partner contributes its know-how and experience, providing the basis for further industrial development and exploitation of project results.
The MSY concept was included as a principle in the 2009 Green Paper on the reform of the Common Fisheries Policy (CFP) in accordance with the global imperative to manage fish stocks according to the maximum sustainable yield (MSY). This implies a commitment to direct management of fish stocks towards achieving MSY by 2015. Attaining this goal is complicated by the lack of common agreement on the interpretation of 'sustainability' and 'yield' and by the effects that achieving MSY for one stock may have on other stocks and broader ecosystem, economic, or social aspects. MYFISH will provide definitions of MSY variants which maximize other measures of 'yield' than biomass and which account for the fact that single species rarely exist in isolation. Further, MYFISH will redefine the term 'sustainable' to signify that Good Environmental Status (MSFD) is achieved and economically and socially unacceptable situations are avoided, all with acceptable levels of risk. In short, MYFISH aims at integrating the MSY concept with the overarching principals of the CFP: the precautionary and the ecosystem approach. MYFISH will achieve this objective through addressing fisheries in all RAC areas and integrating stakeholders (the fishing industry, NGOs and managers) throughout the project. Existing ecosystem and fisheries models will be modified to perform maximization of stakeholder approved yield measures while ensuring acceptable impact levels on ecosystem, economic and social aspects. Implementation plans are proposed and social aspects addressed through active involvement of stakeholders. Finally, effects of changes in environment, economy and society on MSY variants are considered, aiming at procedures rendering the MSY approach robust to such changes. The expertise of 26 partners from relevant disciplines including fisheries, ecosystem, economic and social science are involved in all aspects of the project. Global experience is engaged from North America and the South Pacific.
Das Projekt ist getragen von der Vision der 'Integrierten Verbundproduktion auf Basis nachwachsender Rohstoffe' und der durchgängigen Entwicklung vom Labor- bis zum Produktionsmaßstab. Dieser Ansatz ist neuartig und wurde bisher noch nicht realisiert. Die durchgängige Entwicklung von Prozessen und Verfahren zur Nutzung nachwachsender Rohstoffe vom Labor- bis zum Produktionsmaßstab in einer Bioraffinerie ist ein entscheidender Faktor für die erfolgreiche Umsetzung des vorgeschlagenen Konzeptes. AP7.1: Erfassung der ökonomischen und ökologischen Kenngrößen der Rohstoffbereitstellung. AP7.2: Definition der Systemgrenzen der Teilprozesse sowie der vier Produktlinien. AP7.3: Erfassung der Stoff- und Energieströme mit einem Stoffflussanalysewerkzeug. AP7.4: Ökonomische, ökologische und soziale Bewertung der Teilprozesse. AP7.5: Produktbewertung. Für das Institut für Industriebetriebslehre und Industrielle Produktion (IIP) der Universität Karlsruhe (TH) stellen die Ergebnisse des Vorhabens einen wichtigen Schritt zur Entwicklung eines in sich geschlossenen Instrumentariums zur ökonomischen, ökologischen und sozialen Bewertung von Nutzungskonzepten von Biomasse sowohl aus Prozess- als auch aus Produktsicht dar. Die entwickelten und angepassten Methoden und Werkzeuge können auf weitere Produkte und Prozesse zur Nutzung von Biomasse übertragen werden. Darüber hinaus werden die methodischen Ergebnisse in wissenschaftlichen und industriellen Fachzeitschriften publiziert und finden Eingang in die Lehre des Institutes.
The BECA (Balanced European Conservation Approach - ICT services for resource saving in social housing) project addresses the need to reduce energy consumption in European social housing by a very significant amount to meet overall emission reduction targets. To substantially reduce peak and overall demand for energy and water across EU social housing, BECA will develop a full set of innovative services for resource use awareness and resource management. Balance is achieved by addressing not only energy but water, by including all key energy forms - electricity, gas and heating - and by including strong activities in Eastern Europe as well as in the North, South and West of the EU. Social housing organisations in 7 European countries (Germany, Italy, Spain, Sweden, Bulgaria, Czech Republic, Serbia) and their partners are cooperating in the project to provide ICT-based energy management and energy awareness services directly to social housing tenants and service operators. Services will be piloted by approx. 5,000 social housing tenants across 7 sites in 7 European countries. Sustained reductions in resource use are to be achieved through usable ICT-based services directly to tenants, as well as by effective monitoring and control of local power generation and, for district heating, the full heat delivery chain. Intensive work will be addressed to optimising services for tenants and maximising impact on resource use behaviour. Service requirements will be investigated with tenants and staff and service prototypes based on initial use cases will be subject to user testing within the first year of the project. Results are used to finalise service design in a second iteration of use case definition and service specification lasting some 8 months, cumulating in implementation of operational services at all the 7 pilot sites. Pilots at sites will operate for at least 14 months; lead sites will be identified to being operation early and provide example solutions to others. The consortium, led by social housing providers and public authorities includes global ICT and service providers and distribution network operators working with local consultants and specialist advisors to carry out all steps in service implementation.
ADAMANT is an ambitious professorship program aimed at understanding and modeling, at a coherent level of detail, coupled Alpine environmental processes in the mountain, piedmont and lowland. The hypothesis is that such an understanding will provides fundamental insights to the (non-traditional) use of water in the riparian ecosystem, and therefore explain why and how changes in river hydrology due to water impoundment will affect the riparian biodiversity across space and time scales. These points define the research objectives targeted by ADAMANT: 1. The assessment of the origin and the role of nonlinearities in the routing dynamics of glacierized basins, and related linkages to the probabilistic behaviour of equilibrium snowlines; 2. The experimental definition of (objective) benefit functions for the use of water by the riparian environment in relation to the statistical effects of both floods and moderate flows; 3. The (analytical and numerical) solution to the optimal water allocation problem between traditional and non-traditional water uses under changing scenarios such climatic, economic, operational. The project ADAMANT will accordingly be carried out in 3 interconnected research modules involving 2 Ph.D's and one Postdoc. The work foreseen in ADAMANT will account for field monitoring campaigns and experiments, linear and nonlinear data analysis, and modelling of the above said mountain, piedmont and lowland processes. In particular, the mathematical modelling approach will be of minimalist type whenever a fully physically based (distributed) approach is precluded or not convenient to reproduce statistically significant long-term scenarios. In this manner, overparametrization due to excessive model complexity will be avoided on the one hand, and the model will remain mathematically tractable for the possible search of elegant analytical solutions, on the other hand. ADAMANT research goals are particularly interesting in a time when energy production from hydropower is still among the most used techniques, especially in glacierized basins of alpine countries. From a practical viewpoint ADAMANT will help define new operational rules and guidelines for Environmental Flow Requirements. Overall, this project will provide an integrated and sustainable water management study in impounded alpine riparian ecosystems, and in harmony with present and future countrywide plans of river restoration and renaturalization strategies.
Background: Aquaculture significantly contributes to protein supply and cash income of Black Thai farmers in Yen Chau, Son La province, Northern Vietnam. Fish is produced for cash income (2/3rd) and subsistence (1/3rd) while self recruiting species (small fish, crustaceans and molluscs) provide additional protein for home consumption. The current aquaculture system is a polyculture of the macroherbivorous grass carp as main species together with 3-5 other non-herbivorous fish species like Common Carp, Silver Carp, Bighead Carp, Mud Carp, Silver Barb and Nile Tilapia. With a rearing period of 21 months, the productivity of the aquaculture system amounts to 1.54 +- 0.33 t ha-1 a-1 and can be characterized as low. Nearly each household has at least one pond, which serves multiple purposes and is operated as a flow-through-system. The steady water flow is advantageous for the culture of grass carp, but causes a continuous loss of nutrients and high turbidity and thereby limits the development of phytoplankton and zooplankton which are natural food for non-herbivorous species. The farmers are using mainly green leaves (banana, bamboo, cassava, maize and grass) and crop residues (rice bran, rice husk, cassava root peel, distillery residue) as feed input, which is available to Grass Carp while non-herbivorous fish species are not fed specifically. Manure is used as fertilizer. The uneaten parts of fed plants are sometimes accumulating in the pond over several years, resulting in heavy loads of organic matter causing oxygen depletion. Anaerobic sediment and water layers limit the development of zoobenthos and may provide a habitat for anaerobe disease agents. Since 2003 an unknown disease condition has been threatening Grass Carp production and is having a major economic impact on the earnings from fish farming in Yen Chau region. Other fish in the same ponds are not affected. Especially in March-April and in September-October the disease is causing high morbidity and mortalities of Grass Carp in affected ponds and is thereby decreasing the dietary protein supply and income generation of Black Thai farmers. Little is known about the definition or aetiology of the disease condition.
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