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Global climate
(2011)
The article discusses the process and outcomes along the central "building blocks" of the negotiations. According to the Bali Action Plan, the negotiations are proceeding under two tracks. First, the "Ad Hoc Working Group on Further Commitments by Annex I Countries under the Kyoto Protocol (AWG-KP)", which was established at CMP 1 in Montreal in 2005, is negotiating future emission targets for industrialised countries (listed in Annex I of the UNFCCC). Second, while the "Ad Hoc Working Group on Long-term Cooperative Action under the Convention (AWG-LCA)" also negotiates commitments for Annex I countries, in practice this was originally deemed to relate in particular to those that have not ratified the Protocol - that is, the USA. In addition, the AWG-LCA negotiates "nationally appropriate mitigation actions (NAMAs)" of developing countries, which are to be supported and enabled by industrialised countries through technology, financing and capacity building. Both the NAMAs and the support are to be undertaken in a measurable, reportable and verifiable manner. Finally, the AWG-LCA negotiates ways to enhance adaptation efforts of developing countries, which are also to be financially and technologically supported by industrialised countries.
The challenges of resource efficiency and appropriate strategies : a special issue in "SAPIENS"
(2011)
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.
The purpose of the paper is to share the findings of a European innovation transfer project (2008-2010) for strengthening sustainability in European handicraft with the aim of transferring a German qualification and consulting concept. The focus of the paper is a train-the-trainer design, which was developed, tested and evaluated with regard to the specific qualification needs and the existing qualification concepts of five European countries. The paper provides content, didactic approach and methods of the train-the-trainer design and the key results of the related analysis of research data. Furthermore, the train-the-trainer design is embedded within the project approach, the methodology of realising an innovation transfer and the associated project products. The results of the train-the-trainer design evaluation are reflected upon with regard to starting points of a European qualification concept for sustainability in handicraft.
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.
Technical innovations can contribute significantly to increase resource efficiency. A selection of 21 examples for resource efficient technologies, products and strategies from the field shows the brochure Resource Efficiency Atlas, which was created in line with the same titled project. Overall the project team analysed several hundred technical solutions and strategies and assessed its possible contributions to increases in resource efficiency. The project was arranged co-operatively by the Fraunhofer Institute for Industrial Engineering IAO, the Trifolium-Beratungsgesellschaft mbH and the Institut für Arbeitswissenschaften und Technologiemanagement of the University Stuttgart. The examples from the brochure and further 70 examples can be seen on the project website www.ressourceneffizenzatlas.de.
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.
International consensus is growing that a transition towards a low carbon society (LCS) is needed over the next 40 years. The G8, the Major Economies Forum on Energy and Climate, as well as the Ad Hoc Working Group on Long-term Cooperative Action under the United Nations Framework Convention on Climate Change, have concluded that states should prepare their own Low-emission Plans or Low-emission Development Plans and such plans are in development in an increasing number of countries.
An analysis of recent long-term low emission scenarios for Germany shows that all scenarios rely heavily on a massive scale up of energy efficiency improvements based on past trends. However, in spite of the high potential that scenario developers assign to this strategy, huge uncertainty still exists in respect of where the efficiency potentials really lie, how and if they can be achieved and how much their successful implementation depends on more fundamental changes towards a more sustainable society (e.g. behavioural changes).
In order to come to a better understanding of this issue we specifically examine the potential for energy efficiency in relation to particular demand sectors. Our comparative analysis shows that despite general agreement about the high importance of energy efficiency (EE), the perception on where and how to achieve it differ between the analysed scenarios. It also shows that the close nexus between energy efficiency and non-technical behavioural aspects is still little understood. This leads us to the conclusion that in order to support energy policy decisions more research should be done on energy efficiency potential. A better understanding of its potential would help energy efficiency to fulfil its role in the transition towards a LCS.
The general conditions for local authorities in Germany have changed fundamentally during the last decades. Not only do municipalities compete with each other for employment, prestige and competitive advantages, they also face increasingly higher demands by their citizens, for instance in the area of climate protection.
Therefore, every municipality has to consider various economic, social and ecological determinants in its decision-making processes. With respect to public buildings, an economically-oriented cost-benefit-analysis alone is not adequate due to a municipality's role as "consumer and role model". To identify measures with a broader benefit, a multicriteria analysis (MCA) has been used to analyze energy efficiency measures in public buildings for the city of Dortmund.
For several years Dortmund has committed itself to implement energy efficiency measures and improve the energy performance of its building stock. Nevertheless, a benchmark analysis still shows a high energy saving potential that cannot be tapped with the existing measures and instruments. Therefore, a package of measures has been developed in close cooperation with the city of Dortmund, ranging broadly from measures of energetic retrofitting and green IT to behavioral change of building occupants.
In the MCA these measures have been assessed according to ten different criteria such as innovativeness, cost effectiveness, external costs, CO2 reduction potential, local value or effort of implementation. Three different scenarios ("City as Role Model", "City as Homo Oeconomicus", "City as Climate Protector") show different municipal perspectives.
The analysis has shown that the greatest benefit for municipalities, regardless of the municipal perspective, is yielded by measures such as voluntarily enhanced minimum standards for new or for energetic retrofitting of public buildings, the procurement of energy-efficient office equipment, the expansion of heat generation from renewable energies and the usage of private capital in participatory projects like "Solar&Save".
What are the best policies and measures to stimulate energy efficiency in buildings? The debate around this is at least as diverse as the markets and concepts for energy efficiency in buildings, and often quite controversial. However, no magic formula seems to have been found so far. It is, therefore, time to address the question in a new way - by combining both theoretical evidence on what policy support markets need, and empirical evidence on which combinations or packages of policies have worked.
In the context of its new four-year project bigEE - "Bridging the Information Gap on Energy Efficiency in Buildings", the Wuppertal Institute is implementing this new approach. The bigEE project aims at developing an international internet-based knowledge platform for energy efficiency in buildings. Hence, it must provide evidence-based information. On the theoretical side, the analysis starts with value chains in the building sector and the barriers but also actor-inherent incentives that the different types of market participants face. This enables to identify, which policies and measures need to be combined to jointly overcome the barriers and strengthen the incentives. On the empirical side, model examples of good practice are collected and compared. The search for these is guided by the results of the theoretical analysis, international expert opinion, and existing databases and platforms. In order to identify what is "good practice", the project uses a newly developed multi-criteria assessment scheme. Finally, the impacts achieved with the model examples, lessons learned, and their transferability will be used to validate the model policy package identified in the theoretical analysis.
The public launch of the bigEE platform is planned for autumn of 2011; eceee Summer Study participants will get a first glance at its content through this paper. The paper presents the methods and tools used and showcases their application for the case of new buildings
The German contribution to limiting global warming to two degrees has to be - as in other developed countries, too - a reduction of 80 to 95 percent of CO2 emissions by 2050 compared to 1990. The project "Low Carbon City Wuppertal 2050" has analysed how such a drastic reduction of CO2 could be achieved on a municipal level in the transportation and residential sector by also working on the land use and material flows dimension. The focus of this paper lies on the space heating in the residential sector.
Wuppertal is a city with about 350,000 inhabitants in the West of Germany. According to the CO2 balance (2007) of the city that was adjusted to the year 2010, the emissions that were caused by space heating in the residential sector remained almost the same since 1990. They decreased slightly from 693,000 tons CO2 in 1990 to 691,000 tons in 2010, although final energy use for space heating increased by about 15 percent. But the shift of energy sources especially from coal to gas avoided an increase of emissions. However, the reduction target of 95 percent means that CO2 emissions have to be reduced to 35,000 tons per year until 2050.
A reference scenario shows that the city could achieve about 30 percent of the reduction required with the current trend of renewable energy development and energy efficiency measures such as retrofitting the building stock. But looking at the difficult financial conditions of the municipality as well as at the socio-economic situation of the inhabitants it becomes clear that the remaining 65 percent of the target to a 95 percent reduction will be difficult to reach and that innovative measures of energy efficiency and sufficiency1 need to be developed.
But which social-ecological effects does the implementation of comprehensive climate protection measures have on the inhabitants of a city? How do people live in a "Low Carbon City"? In this paper qualitative and quantitative scenarios will be developed since the combination of both is promising to show both effects: what share could renewable energies, energy efficiency and sufficiency measures have in reaching the target of 95 percent, and how could life look like in an almost CO2 free city in Germany in 2050.
In 2008, transport accounted for 27% of the world’s total final energy consumption. Currently, we are facing a rapidly expanding transport sector with continually increasing energy consumption. In the future, emerging and developing countries especially will experience an accelerated growth in transport energy demand due to rapid population growth, urbanisation and rising per capita income. The transport sector’s inefficiency and its dependency on oil will become an economic burden for these countries. They will have to face increasing crude oil prices and uncertainties regarding energy security.
Thus, there is a need for an efficient transport system and particularly for decision makers in developing and emerging countries to have access to planning advice in order to identify suitable and effective measures for low-energy urban transport. To meet this demand, existing knowledge and measures about energy efficiency in urban passenger transport was compiled and a structured introduction to energy efficiency in transport is provided.
The main determinates of an energy-efficient transport system are explained and strategic approaches to increase energy efficiency are outlined. Success factors and barriers for energy efficiency policies are described. The main element of the paper is an overview of different energy efficiency policies and measures for the key actors in energy-efficient transport on local and national levels. A set of measures is assigned to each actor identified. The compilation was adapted to the circumstances in developing and emerging countries and includes examples for successful implementation of several measures. Thus, the document satisfies the need for a comprehensive introduction to energy efficiency in urban transport in developing and emerging countries.
This paper analyses drivers for resource use and material productivity acrosscountries. This is not only relevant in light of soaring raw material prices but also because EU policies, such as the "Thematic Strategy on the Sustainable Use of Natural Resources" (COM [2005] 670), the EU Raw Materials Initiative (COM [2008] 699) and various similar policies internationally, seek to better manage materials along their life-cycle and across economies. In order to better understand the system dynamics of material use, our paper applies methodologies of material flow analysis and regression analysis to identify the major drivers for resource use and decoupling from GDP. Drivers are understood as those factors that exert influence on human activities to use resources. A panel data set is taken for the European Union for the years 1980–2000 (EU-15) and 1992–2000 (EU-25). The main drivers of resource use were found to be energy efficiency, new dwellings and roads construction activities. Shortcomings of the methodology are also discussed.
The representative survey studies provide a comprehensive database on the public awareness and perception of CCS in six selected European countries. Our results provide insights into the public understanding and knowledge of energy related issues and CCS topics. The embedded experimental research provides insights into how information affects CCS perceptions. The results discuss implications for CCS communication methods.
This report analyses the international climate negotiations that took place at the 16th Conference of the Parties to the UNFCCC held in Cancún in December 2010. It discusses the negotiation process on the following central "building blocks" of the negotiations: the legal form of a future agreement, mitigation, measuring, reporting and verification, adaptation, finance, technology and reducing emissions from deforestation and forest degradation (REDD). The report discusses the results in detail and concludes with an outlook on how the challenges ahead could be overcome.
CCS is discussed in a broad sense throughout Europe. In this paper a cautious, conservative estimate of CO2 storage capacity for Germany and its neighbouring countries where CO2 emissions from Germany could possibly be stored (Netherlands, France, Denmark, Norway, UK and Poland) is presented. Such a lower limit calculation is necessary for orientation purposes for potential investors and political decision-makers.
Conservative CO2 sequestration capacity in deep saline aquifers for Germany is derived by the volumetric approach where parameters such as efficiency factor, CO2 density, porosity of the geological formation are of interest. It is assumed that every geological system is closed and thus an efficiency factor of 0.1 per cent (based on maximum pressure increase and total compressibility) for saline aquifers is applied. The capacity of German depleted oil and gas fields is based on cumulative recovery data and a sweep efficiency of 75 per cent. The storage capacity in the other considered countries, adjacent to Germany, are based on a critical review and adjustment of the results of the European reports JOULE II, GESTCO and GeoCapacity.
The conservative capacities for all countries together amount to 49 Gt CO2, from which Norway and the UK provide 36 Gt, all offshore in the North Sea. Compared to the emissions from large point sources in these countries during 40 years (47.6 Gt of CO2), a virtual balance is achieved. This can only be reached, if a large scale CO2 pipeline system is installed to connect these countries, especially Germany, to the large sinks in the North Sea. If additional restrictions like source-sink matching, acceptance issues and injection rates constraints are taken into account, the available storage space gets increasingly scarce.
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.
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.