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MED-CSP Concentrating Solar Power for the Mediterranean Region WP0: Introduction

This project focuses on the development of Concentrating Solar Power (CSP) technologies for the Mediterranean region. It aims to achieve sustainability goals, promote renewable energy technologies, analyze renewable energy resources, assess demand side factors, devise market strategies, evaluate socio-economical and environmental impacts, and provide guidelines for a sustainable energy supply.

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MED-CSP Concentrating Solar Power for the Mediterranean Region WP0: Introduction

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  1. MED-CSP Concentrating Solar Power for the Mediterranean Region WP0: Introduction WP1: Sustainability Goals WP2: Renewable Energy Technologies WP3: Renewable Energy Resources WP4: Demand Side Analysis WP5: Scenario & Market Strategies WP6: Socio-Economical Impacts WP7: Environmental Impacts

  2. Guidelines for a sustainable energy supply Equality of access: Equal opportunities in accessing energy resources and energy services shall be assured for all. Protection of resources: The different energy resources shall be maintained for the generations to follow, or there shall be comparable options created to provide sufficient energy services for future generations. Environmental compatibility: The adaptability and the ability for regeneration of natural systems (the “environment”) may not be exceeded by energy-related emissions and waste. Risks for human health – by e.g. an accumulation of problematical pollutants and harmful substances – shall be avoided. Social compatibility: It shall be assured when realising the energy supply systems that all people affected by the system are able to participate in the decision-making processes. The ability of economic players and communities to act and shape may not be restricted by the systems being set up, but rather shall be expanded wherever possible. Error tolerance and low risk: Unavoidable risks and hazards arising from the generation and use of energy shall be minimised and limited in their propagation in space and time. Human errors, improper handling, wilful damage, and incorrect use shall also be taken into consideration in the assessment. Economic efficiency: Energy services shall – in relation to other costs in the economy and of consumption – be made available at acceptable costs. The criterion of “acceptability” refers, on the one hand, to specific costs arising in conjunction with the generation and use of the energy and, on the other hand, to the overall economic costs while taking the external ecological and social costs into consideration as well. Security of supply: The energy required to satisfy the human needs must be available according to the demand and in sufficient quantities, in terms of both time and location. The energy supply must be adequately diversified so as to be able to react to crises and to have sufficient margins for the future and room to expand as required. Efficient and flexible supply systems harmonising efficiently with existing population structures shall be created and maintained. International co-operation: Developing the energy systems shall reduce or eliminate potential conflicts between states due to a shortage of resources and also promote the peaceful co-existence of states by a joint use of capabilities and potentials.

  3. Work Package 1: CO2-Emissions – State and Targets CO2 Emissions calculated according to GHG targets

  4. World wide obligation in 2050 (proposed by WBGU, 2003)

  5. Effect on Energy Sustainability: + positive effect Equality of access Security of Supply Social Compatibility Economic Efficiency Technical Feasibility Protection of Resources International Cooperation 0 uncertain effect Environmental Compatibility Error Tolerance and Low Risk - negative effect Weighing Technology Options for Sustainability Onshore Wind Power Offshore Wind Power Geothermal Hot Dry Rock Biomass Hydropower w. Storage Wave / Tidal Power Solar Thermal Electricity Photovoltaic Nuclear Fission Nuclear Fusion Fossil Plant Efficiency Energy Use Efficiency Long Distance Transmission CO2-Sequestration

  6. Effect on Energy Sustainability: + positive effect Equality of access Security of Supply Social Compatibility Economic Efficiency Technical Feasibility Protection of Resources International Cooperation 0 uncertain effect Environmental Compatibility Error Tolerance and Low Risk - negative effect SEND YOUR OPINION ! Name: .................................... Onshore Wind Power Offshore Wind Power Geothermal Hot Dry Rock Biomass Hydropower Wave / Tidal Power Solar Thermal Electricity Photovoltaic Nuclear Fission Nuclear Fusion Fossil Plant Efficiency Energy Use Efficiency Long Distance Transmission CO2-Sequestration

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