Purpose -Two main activities of the EC FP7 Risk of Energy Availability: Common Corridors for Europe Supply Security (REACCESS) project applied a systematic approach to collect the main characteristics of energy supply corridors starting from mining activities in exporting regions up to the import infrastructures and capacities of EU27þ countries. The aim of the present paper is to summarise identified information on import potentials and the possible corridors for the EU27þ energy supply of the future. This information is used as new starting point for the energy system modelling in the REACCESS project. Design/methodology/approach -Detailed information on existing, planned or potential developments derived from literature reviews and expert surveys, as well as from our own calculations, was compiled in a consistent database. By using suitable geographic information system (GIS) tools, all the identified energy supply routes were represented graphically and analysed with reference to their spatial characteristics. Findings -The information collected was used to generate a comprehensive database of resources, production capacities and import routes. Together with further detailed information on technological and economic parameters (not shown in this paper), this database provides new complete and consistent input for the modelling of import corridors and associated risks regarding the energy systems in Europe. Originality/value -The originality of the paper is the synthesis of a huge volume of information provided in the literature and own additional calculations in a consistent way. The resulting database provides the framework for the integration of security of supply aspects into energy scenario modelling, which is an important modelling challenge and one of the main tasks of REACCESS. The study considers oil, gas, coal and nuclear fuel as well as renewable imports of solar electricity and biomass, and also hydrogen as a possible new energy carrier.
Over the last decades, combating climate change has been an important concern for policy makers. As a result, many policies have been designed towards this direction. Being electricity generation the focus of climate change mitigation policies, important changes are expected in this sector over the next few years as a result of the implementation of such policies. However, electricity production also generates other impacts on the water, energy and land (WEL) nexus that must be further investigated. To shed some light to this issue, this paper presents and discusses the potential impacts on the water-energy-land nexus resulting from the decarbonisation of the Spanish electricity system impacts under two different long-term scenarios. Using a Life Cycle Assessment (LCA) approach, a set of environmental impacts relevant for the nexus have been analysed for the current and future electricity generation technologies in Spain. Additionally, through the use of an optimization energy model-Times-Spain-the evolution of the electricity technologies in Spain until 2030, under two different scenarios and targets has been assessed. Taking into consideration such scenarios, the global warming, acidification, eutrophication, ecotoxicity, water consumption, resource depletion and land use impacts have been estimated. Results show that, over time, together with the decrease of greenhouse gas emission, acidification and eutrophication tend to decrease in both scenarios. On the contrary, ecotoxicity and resource use impacts tend to increase.
Abstract. This work presents the EFDA Times model (ETM), developed within the European Fusion Development Agreement (EFDA). ETM is an optimization global energy model which aims at providing the optimum energy system composition in terms of social wealth and sustainability including fusion as an alternative technology in the long term. Two framework scenarios are defined: a Base case scenario with no limits to CO 2 emissions, and a 450ppm scenario with a limit of 450ppm in CO 2 -eq concentrations set by 2100. Previous results showed that in the Base case scenario, with no measures for CO 2 emission reductions, fusion does not enter the energy system. However, when CO 2 emission restrictions are imposed, the global energy system composition changes completely. In a 450ppm scenario, coal technologies disappear in a few decades, being mainly replaced by nuclear fission technologies which experience a great increase when constrained only by Uranium resources exhaustion. Fission technologies are then replaced by the fusion power plants that start in 2070, with a significant contribution to the global electricity production by 2100. To conclude the work, a sensitivity analysis will be presented on some parameters that may affect the possible role of fusion in the future global energy system.
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