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As illustrated by the case studies of end-of-life vehicles and waste electric and electronic equipment, the approach of an extended producer responsibility is undermined by the exports of used and waste products. This fact causes severe deficits regarding circular flows, especially of critical raw materials such as platinum group metals. With regard to global recycling there seems to be a responsibility gap which leads somehow to open ends of waste flows and a loss or down-cycling of potential secondary resources. Existing product-orientated extended producer responsibility (EPR) approaches with mass-based recycling quotas do not create adequate incentives to supply waste materials containing precious metals to a high-quality recycling and should be amended by aspects of a material stewardship. The paper analyses incentive effects on EPR for the mentioned product groups and metals, resulting from existing regulations in Germany. It develops a proposal for an international covenant on metal recycling as a policy instrument for a governance-oriented framework to initiate systemic innovations along the complete value chain taking into account product group- and resource group-specific aspects on different spatial levels. It aims at the effective implementation of a central idea of EPR, the transition of a waste regime still focusing on safe disposal towards a sustainable management of resources for the complete lifecycle of products.
Concentrated solar power (CSP) plants are one of several renewable energy technologies with significant potential to meet a part of future energy demand. An integrated technology assessment shows that CSP plants could play a promising role in Africa and Europe, helping to reach ambitious climate protection goals. Based on the analysis of driving forces and barriers, at first three future envisaged technology scenarios are developed. Depending on the underlying assumptions, an installed capacity of 120 GWel, 405 GWel or even 1,000 GWel could be reached globally in 2050. In the latter case, CSP would then meet 13–15% of global electricity demand. Depending on these scenarios, cost reduction curves for North Africa and Europe are derived. The cost assessment conducted for two virtual sites in Algeria and in Spain shows a long-term reduction of electricity generating costs to figures between 4 and 6 ct/kWhel in 2050. The paper concludes with an ecological analysis based on life cycle assessment. Although the greenhouse gas emissions of current (solar only operated) CSP systems show a good performance (31 g CO2-equivalents/kWhel) compared with advanced fossil-fired systems (130–900 CO2-eq./kWhel), they could further be reduced to 18 g CO2-eq./kWhel in 2050, including transmission from North Africa to Europe.
Carbon capture and storage (CCS) might be an important climate protection technology for coal-rich countries. This paper presents first results of a systemic and long-term analysis of a future CCS implementation in India. It focuses on potential storage formations in the geological subsurface and the geographic match of these sinks with CO2 emissions of current and future largepoint power plants. The analysis is framed by an overview on India’s position on CCS, ongoing Indian research and development projects as well as its international activities.
The geological potential for CO2 sequestration in India is subject to large uncertainty because, so far, only few studies estimated it in a vague manner. A first meta-analysis shows that there is a huge variation between 48 Gt and 572 Gt of CO2. The main differences between the evaluated studies are the assumed capacities for deep saline aquifers and basalt formations. Taking the ongoing discussion and the existing uncertainties into account, the storage potential might be provided only by aquifers (in the range of 44 to 360 Gt of CO2) and hydrocarbon fields (2 to 7 Gt of CO2).
The amount of CO2 emissions possibly available for sequestration is assessed by applying three substantially different long-term energy scenarios for India. These scenarios, indicating pathways between a "low carbon" and a "high carbon" development until 2050, result in cumulated CO2 emissions between 30 and 171 Gt if all new large-scaled power plants will be based on CCS from 2020 on. Compared with the sink capacities, only the CO2 emissions of scenario S2 (30 Gt) could theoretically be stored with high certainty. Considering the scenarios S3 and S1, their CO2 emissions (94 Gt and 171 Gt, respectively) could only be sequestered if the aquifer capacity would prove to be usable. Geological storage sites do not appear to be located close to sources in South West, Central, North and North East India. This first rough analysis means that only those CO2 emissions occurring in the Western parts of North and West India, the Eastern part of South India as well as the South part of East India might be suited for sequestration nearby.
A more detailed source-sink matching will follow in the next phase of the project, including results of expert meetings in India. Furthermore, this analysis will be complemented by an additional assessment from economic, ecological and resource-strategic points of view, which might further affect the potential for CCS.
Um das vom Weltklimarat (IPCC) geforderte 2°C-Ziel einhalten zu können, ist eine Reduktion der globalen CO2-Emissionen um 80% bis 2050 gegenüber dem Stand von 1990 zwingend notwendig. Hierbei wird auch solarthermischen Kraftwerken eine immer größere Bedeutung beigemessen. Im BLUE Map-Szenario der Internationalen Energieagentur (IEA), das von einer CO2-Reduktion um 50% bis 2050 gegenüber 2005 ausgeht, müssen im Jahr 2050 ca. 11% (4.754 TWh) des weltweiten Strombedarfs durch Sonnenenergie gedeckt werden (IEA 2008). Neben Photovoltaik sollen solarthermische Kraftwerke (Concentrated Solar Power, CSP) etwa 46% (ca. 2.200 TWh) der prognostizierten Menge an Solarstrom erzeugen. Im Energy[R]evolution Szenario von Greenpeace International und EREC (European Renewable Energy Council) aus dem Jahr 2008 werden rund 6.000 TWh an CSP-Strom im Jahr 2050 angenommen (bei einer installierten Leistung von 801 GW), während andere Studien bis zu 1.000 GW installierter Leistung in 2050 betrachten (Viebahn et al. 2010). Die DESERTEC-Initiative gibt ein Ziel von 5.000 GW installierter Leistung im Jahr 2050 vor.
Der Export von CSP-Technologien in die "Sunbelt"-Regionen bietet große Chancen für deutsche Anlagenbauer. So sind u.a. Schott Solar, die Ferrostaal Group mit ihrem Geschäftssegment "Solar Energy", Flagsol, die Solar Power Group, Solar Millenium und Fichtner Solar auf dem Gebiet CSP aktiv. Schott Solar (Receiver) und Flabeg (Spiegel) haben eine weltweit führende Markstellung inne. Große deutsche Energieversorger und Anlagenbauer wie E.On, RWE und Siemens gehören zum Industriekonsortium der Desertec Industrial Initiative, die den Ausbau von CSP in der MENA-Region vorantreiben will. Die Initiative wurde von der Münchener Rück angestoßen.
In diesem Artikel wird dargestellt, welche Aktivitäten deutsche Unternehmen entlang der Wertschöpfungskette bislang aufweisen und wie ihre Marktstellung im Vergleich zu führenden internationalen Unternehmen zu bewerten ist. Anschließend wird auf Basis von vorliegenden Energieszenarien ermittelt, welche messbaren ökonomischen Effekte für deutsche Unternehmen, z.B. zusätzliche Wertschöpfung und die Schaffung neuer Arbeitsplätze, aus den genannen Potentialen resultieren. Die Ergebnisse basieren auf einer Studie des Wuppertal Instituts, die im Auftrag von Greenpeace Deutschland und der DESERTEC Foundation erstellt wurde.
Nationale und internationale Umweltdebatten fokussieren oft auf das Ziel, eine Senkung der Treibhausgasemissionen zur Schonung des Klimas zu erreichen. Entsprechend stehen die Themen "Erneuerbare Energien" und "Energieeffizienz" vermehrt im Vordergrund. Die Ökodesign-Richtlinie 2009/32/EG war ein Beispiel für diese Vorgehensweise. Obwohl die Richtlinie prinzipiell alle Umwelteffekte im Lebenszyklus eines Produktes in den Blick nimmt, lag der Fokus der bislang beschlossenen Durchführungsmaßnahmen auf der Steigerung der Energieeffizienz.
Im Rahmen der Richtlinie wurde bereits bedeutsam in die Gestaltung von energiebetriebenen Produkten wie z. B. Kühlschränken und Lampen eingegriffen und durch die erlassenen Mindesteffizienzanforderungen ein entscheidender Beitrag geleistet, die CO2-Emissionen zu reduzieren.
Mit der geänderten Ökodesign-Richtlinie 2009/125/EG wurde der Geltungsbereich auf energieverbrauchsrelevante Produkte erweitert, so dass sich die Frage stellt, ob im Zuge dieser Erweiterung andere Umweltziele stärker in den Mittelpunkt rücken. Zwar spielt die Wirkung auf den Energieverbrauch auch bei zahlreichen nichtenergiebetriebenen bzw. energieverbrauchsrelevanten Produkten eine entscheidende Rolle, doch gerade die Frage, welche weiteren Ressourcen bei den einzelnen Produktgruppen klimapolitisch bedeutsam sind, muss produktspezifisch neu beantwortet werden.
Vor diesem Hintergrund wird dieser Artikel aufzeigen, welche Fragen bei der Untersuchung neuer Produktgruppen wie z. B. Dämmstoffe und Fenstern aufkommen werden und es wird eine erste Einschätzung gegeben, wie eine neue Ressourcenbetrachtung innerhalb der Ökodesign-Richtlinie aussehen kann.
Domestic emission trading systems in Non-Annex I countries : state of play and future prospects
(2011)
Since the adoption of the Kyoto Protocol in 1997, the establishment of a harmonised international carbon market has been seen as one of the main strategies in international climate policy. So far, however, the market is far from being globally harmonised or systematically linked. Instead, a mosaic of national and sub-national markets has been under development, differing in timing, location, relationship to the Protocol and their levels of legal commitment.
Nevertheless, creating a global carbon market is a key goal of EU climate policy. As plans for the establishment of emissions trading systems (ETS) emerge in various non-Annex I countries, prospects for linking them to existing systems seem to finally get in reach. We have analysed the prospects of emission trading in non-Annex I countries in a recent paper on behalf of the German environment ministry. In the following we first give a theoretical overview of what design factors need to be taken into account when establishing national emission trading systems. The following elaborates on the status of emissions trading discussion in various non-Annex I countries.
This report analyses the international climate negotiations at the UN climate conference in Durban in December 2011. The conference revolved around two key sets of issues: What will be the overarching long-term framework of international climate policy and what near-term action will be taken to combat climate change? Accordingly, the first part of the report is devoted to the negotiations and outcome on the legal form of the future climate regime while the second part discusses near-term action along the "building blocks" of the Bali Action Plan.