This article addresses informational barriers to energy efficiency. It is a widely acknowledged result that an energy efficiency gap exists implying that the level of energy efficiency is at an inefficiently low level. Several barriers to energy efficiency create this gap and the presence of asymmetric information is likely to be one such barrier. The article finds that problems of moral hazard and adverse selection indeed can help explain the seemingly low levels of energy efficiency. The theory reveals two implications to policies on energy efficiency. First, the development of measures to enable contractual parties to base remuneration on energy performance must be enhanced, and second, the information on technologies and the education of consumers and installers on energy efficiency must be increased. Finally, it is found that the preferred EU policy instrument on energy efficiency, so far, seems to be the use of minimum requirements. Less used in EU legislation is the use of measuring and verification as well as the use of certifications. Therefore, it is concluded that the EU should consider an increased use of these instruments.
Biogas and bio-methane that are based on energy crops are renewable energy carriers and therefore potentially contribute to climate protection. However, significant greenhouse gas (GHG) emissions resulting from agricultural production processes must be considered. Among those, the production and use of fertilizer, and the resulting leaching of nitrous oxide (N2O), are crucial factors. This article provides an integrated life cycle assessment (LCA) of biogas (i.e. bio-methane that has been upgraded and injected into the natural gas grid), taking into account the processes of fermentation, upgrading and injection to the grid for two different types of biogas plants. The analysis is based on different feedstocks from crop rotation systems for different locations in Germany. A special focus is on the sensitivity of assumptions of nitrous oxide emissions to overall GHG emissions. Much research exists on the measurement or modeling of the actual N2O emissions that result from farming processes. Since there is as yet no precise regional data, most analyses use tier-1 data from the IPCC national GHG inventories as a default. The present article coincides with recent research in indicating that this data varies at the regional level. However, it is not the scope of the article to evaluate the quality of existing data for N2O emissions, but to show the effects of different assumptions on the LCA of GHGs from bio-methane. Thus, a link between the provision of emission data and the practical implementation of biogas technology is provided. The main result is that the supply chain of substrates from agricultural processes appears to contribute the most to the GHG emissions of bio-methane. The "worst case" scenario where 5% of the nitrogen fertilizer used is emitted in form of N2O shows that the GHG mitigation potential of bio-methane versus natural gas is very small, so there is not much margin for error in the plant technology.
Hintergrund: Die Bezugsquellen und Transportwege von fossilem Erdgas werden sich in den kommenden beiden Dekaden diversifizieren. Veränderungen der Lieferstruktur, verbunden mit weiteren Transportentfernungen und dem Neubau von Pipelines sowie der verstärkte Einsatz von verflüssigtem Erdgas (LNG - Liquefied Natural Gas) sind zu erwarten. Entsprechend werden sich auch die vorgelagerten Prozessketten und die damit verknüpften THG-Emissionen verändern. Im Sinne einer korrekten und ganzheitlichen Bilanzierung der Lebenszyklusemissionen und weitgehender Treibhausgasminderungsziele, sind die vorgelagerten Emissionen eine nicht zu vernachlässigende Größe. Gleichzeitig wird Biomethan als Beimischung zum fossilen Erdgas an Bedeutung gewinnen. Obwohl seine Verbrennung als klimaneutral gewertet wird, sind die Prozesse zur Herstellung von Biomethan mit Emissionen verbunden.
Die Treibhausgasemissionen (THG) der Vorketten von in der EU eingesetzten Energieträgern werden in der neuen EU-Kraftstoffqualitätsrichtlinie (vom Dez. 2008) reguliert. Ihre Höhe und ihre Entwicklung wird für die klimapolitischen Diskussionen und politische Entscheidungen somit immer wichtiger.
Ziel: Vor dem Hintergrund der angesprochenen Aspekte sollen die zukünftige Entwicklung der Gasversorgung in Deutschland und die Veränderungen der vorgelagerten THG-Emissionen von Erdgas und Biomethan ermittelt werden. In zwei Szenarien werden die mit der Herstellung und dem Transport von Erdgas und Biomethan verknüpften Emissionen bis zum Jahr 2030 einschließlich des zu erwartenden technischen Optimierungspotenzials bilanziert. Mittels dieser Analyse können Einschätzungen der zukünftigen Emissionspfade und der durchschnittlichen Emissionen (Klimaqualität) des eingesetzten Gases (als Mischung fossiler und biogener Gase einschließlich der damit verbundenen Prozesskettenemissionen) gegeben werden. Diese können als Grundlage für energie- und klimapolitische Entscheidungen dienen.
Ergebnisse und Diskussion: Nach Erläuterung der Prozesskette von Biomethan werden die zu erwartenden technischen Entwicklungen der einzelnen Prozessschritte (Substratbereitstellung, Fermentierung, Aufbereitung, Gärrestnutzung) diskutiert und die Höhe der hiervon zu erwartenden Emissionen bilanziert. Basis sind Ergebnisse der wissenschaftlichen Begleitforschung des Wuppertal Instituts zur Einspeisung von Biomethan ins Erdgasnetz. Dabei gehen wir davon aus, dass die nächste Anlagengeneration "optimierte Technik" das aus heutiger Sicht bestehende Optimierungspotenzial des heutigen Stands der Technik ausschöpfen wird, sodass sich die spezifischen, auf den Heizwert des Biomethan bezogenen, THG-Emissionen der Vorkette von aktuell 27,8 t CO2-Äq/TJ auf 14,8 t CO2-Äq/TJ in 2030 fast halbieren werden.
Die zu erwartenden Emissionen der Erdgasprozesskette wurden in einem Vorgängerartikel bereits im Detail analysiert. Bei der Förderung und der Transportinfrastruktur ist ebenfalls eine Optimierung der Technik zu erwarten. Die dadurch erzielte Verringerung der spezifischen THG-Emissionen kann die aus den künftig längeren Transportstrecken und aufwendigen Produktionsprozessen resultierende Erhöhung ausgleichen.
Abschließend werden zwei Szenarien (Hoch- und Niedrigverbrauch) der künftigen Gasversorgung Deutschlands bis 2030 aufgestellt. Im Hochverbrauchszenario wird damit gerechnet, dass der Gaseinsatz in Deutschland um 17 % steigen wird. Im Niedrigverbrauchszenario wird er dagegen um etwa 17 % sinken. Gleichzeitig wird der Anteil von Biomethan am eingesetzten Gas auf 8 bzw. 12 % ansteigen. Die - direkten und indirekten - Treibhausgasemissionen der Gasnutzung in Deutschland werden im Niedrigverbrauchszenario um 25 %, d. h. überproportional von 215,4 Mio. t CO2-Äq auf 162,4 Mio. t CO2-Äq zurückgehen. Im Hochverbrauchsszenario steigen die Gesamtemissionen leicht um 7 % (auf 230,9 Mio. t CO2-Äq) an.
Schlussfolgerungen: Gasförmige Energieträger werden in den kommenden beiden Dekaden eine zentrale Säule der deutschen Energieversorgung bleiben. Insgesamt zeigt sich, dass die THG-Emissionen der Nutzung von Erdgas v. a. von den Verbrauchsmengen der Gasversorgung abhängig sind. Das heißt, dass sowohl aus klima- als auch aus energiepolitischer Sicht die Steigerung der Energieeffizienz ein zentraler Faktor ist. Daneben bestehen sowohl in der verstärkten Nutzung von Biomethan als auch in der weiteren Investition in emissionsoptimierte Technologien entlang der Vorketten signifikante Emissionsminderungspotenziale. Hierdurch kann die "Klimaqualität", d. h. die spezifische Treibhausgasemissionshöhe über alle Prozessstufen, des eingesetzten Gases deutlich verbessert werden. Die spezifischen Gesamtemissionen pro TJ eingesetzten Gases werden hierdurch um ca. 9 % von heute 63,3 t CO2-Äq pro TJ auf etwa 54,5 t/TJ sinken. Entscheidend ist hierfür der verstärkte Einsatz von Biomethan, dessen Verbrennung aufgrund der biogenen Herkunft des Kohlenstoffs weitgehend klimaneutral ist (im Vergleich zu direkten Emissionen von 56 t CO2/TJ bei der Verbrennung von Erdgas oder 111 t CO2/TJ bei z. B. Braunkohle). Die Vorteile der gasförmigen Energieträger in der Klimaqualität und effizienten Nutzung werden - insbesondere auch in der künftig zu erwartenden Beimischung von Biomethan - auch zukünftig Bestand haben.
This paper undertakes a step to explaining the international economics of resource productivity. It argues that natural resources are back on the agenda for four reasons: the demand on world markets continues to increase, the environmental constraints to using resources are relevant throughout their whole life cycle, the access to critical metals could become a barrier to the low carbon economy, and uneven patterns of use will probably become a source of resource conflicts. Thus, the issue is also of relevance for the transition to a low carbon economy. "Material Flow Analysis" is introduced as a tool to measure the use of natural resources within economies and internationally; such measurement methodology now is being harmonized under OECD auspices. For these reasons, the paper argues that resource productivity - that is the efficiency of using natural resources to produce goods and services in the economy - will become one of the key determinants of economic success and human well-being. An empirical chapter gives evidence on time series of resource productivity increases across a number of economies. Introducing the notion of "material flow innovation", the paper also discusses the innovation dynamics and issues of competitiveness. However, as the paper concludes, market barriers make a case for effective resource policies that should provide incentives for knowledge generation and get the prices right.
This paper reviews the current EU policy framework in view of its impact on hydrogen and fuel cell development. It screens EU energy policies, EU regulatory policies and EU spending policies. Key questions addressed are as follows: to what extent is the current policy framework conducive to hydrogen and fuel cell development? What barriers and inconsistencies can be identified? How can policies potentially promote hydrogen and fuel cells in Europe, taking into account the complex evolution of such a potentially disruptive technology? How should the EU policy framework be reformed in view of a strengthened and more coherent approach towards full deployment, taking into account recent technology-support activities? This paper concludes that the current EU policy framework does not hinder hydrogen development. Yet it does not constitute a strong push factor either. EU energy policies have the strongest impact on hydrogen and fuel cell development even though their potential is still underexploited. Regulatory policies have a weak but positive impact on hydrogen. EU spending policies show some inconsistencies. However, the large-scale market development of hydrogen and fuel cells will require a new policy approach which comprises technology-specific support as well as a supportive policy framework with a special regional dimension.
The papers for this special issue were originally contributed to the 2nd International Wuppertal Colloquium on "Sustainable Growth, Resource Productivity and Sustainable Industrial Policy - Recent Findings, new Approaches for Strategies and Policies" that was held from 10 to 12 September 2009 in Wuppertal, Germany. The intensive discussion during the Colloqium and the subsequent rigorous review process have helped to facilitate this process - we wish to thank all participants and contributers, as well as Sevan Hambarsoomian and Deniz Erdem for administrative support.
This study provides insight into the feasibility of a CO2 trunkline from the Netherlands to the Utsira formation in the Norwegian part of the North Sea, which is a large geological storage reservoir for CO2. The feasibility is investigated in competition with CO2 storage in onshore and near-offshore sinks in the Netherlands. Least-cost modelling with a MARKAL model in combination with ArcGIS was used to assess the cost-effectiveness of the trunkline as part of aDutch greenhouse gas emission reduction strategy for the Dutch electricity sector and CO2 intensive industry. The results show that under the condition that a CO2 permit price increases from €25 per tCO2 in 2010 to €60 per tCO2 in 2030, and remains at this level up to 2050, CO2 emissions in the Netherlands could reduce with 67% in 2050 compared to 1990, and investment in the Utsira trunkline may be cost-effective from 2020–2030 provided that Belgian and German CO2 is transported and stored via the Netherlands as well. In this case, by 2050 more than 2.1 GtCO2 would have been transported from the Netherlands to the Utsira formation. However, if the Utsira trunkline is not used for transportation of CO2 from Belgium and Germany, it may become cost-effective 10 years later, and less than 1.3 GtCO2 from the Netherlands would have been stored in the Utsiraformation by 2050. On the short term, CO2 storage in Dutch fields appears more cost-effective than in the Utsira formation, but as yet there are major uncertainties related to the timing and effective exploitation of the Dutch offshore storage opportunities.
The physical dimension of international trade. Part 1: Direct global flows between 1962 and 2005
(2010)
The physical dimension of international trade is attaining increased importance. This article describes a method to calculate complete physical trade flows for all countries which report their trade to the UN. The method is based on the UN Comtrade database and it was used to calculate world-wide physical trade flows for all reporting countries in nine selected years between 1962 and 2005. The results show increasing global trade with global direct material trade flows reaching about 10 billion tonnes in 2005, corresponding to a physical trade volume of about 20 billion tonnes (adding both total imports and total exports). The share from European countries is declining, mainly in favour of Asian countries. The dominant traded commodity in physical units was fossil fuels, mainly oil. Physical trade balances were used to identify the dominant resource suppliers and demanders. Australia was the principal resource supplier over the period with a diverse material export structure. It was followed by mainly oil-exporting countries with varying volumes. As regards to regions, Latin America, south-east Asian islands and central Asia were big resource exporters, mostly with increasing absolute amounts of net exports. The largest net importers were Japan, the United States and single European countries. Emerging countries like the "Asian Tigers" with major industrial productive sectors are growing net importers, some of them to an even higher degree than European countries. Altogether, with the major exception of Australia and Canada, industrialized countries are net importers and developing countries and transition countries are net exporters, but there are important differences within these groups.
The optimization of value chains is an important process to promote sustainable development, since value chains are closely linked to the satisfaction of human needs and combine different driving forces for environmental change. This article presents a methodological approach for the participatory development of value-chain wide sustainability indicator sets and their integration into a decision support tool in the specific case study of the chain "construction and refurbishment with wood". There are numerous indicator sets for sustainable development of forests and sustainable forestry available at different levels, ranging from local, regional and national to global scale assessments. Some efforts were also made to integrate later production stages of forest value chains (such as wood processing) in the assessment scope (e.g. for chain-of-custody certification). However, no indicator set has so far been available covering environmental, social and economic aspects for the entire value chain of building with timber. This gap was closed through applied sustainability research in the project "Holzwende 2020: Sustainable future markets for wood in the building sector".
Comparative analysis of environmental impacts of maize-biogas and photovoltaics on a land use basis
(2010)
This study aims to stimulate the discussion on how to optimize a sustainable energy mix from an environmental perspective and how to apply existing renewable energy sources in the most efficient way. Ground-mounted photovoltaics (PV) and the maize-biogas-electricity route are compared with regard to their potential to mitigate environmental pressure, assuming that a given agricultural area is available for energy production. Existing life cycle assessment (LCA) studies are taken as abasis to analyse environmental impacts of those technologies in relation to conventional technology for power and heat generation. The life-cycle-wide mitigation potential per area used is calculated for the impact categories non-renewable energy input, green house gas (GHG) emissions, acidification and eutrophication. The environmental performance of each system depends on the scenario that is assumed for end energy use (electricity and heat supply have been contemplated). In all scenarios under consideration, PV turns out to be superior to biogas in almost all studied impact categories. Even when maize is used for electricity production in connection with very efficient heat usage, and reduced PV performance is assumed to account for intermittence, PV can still mitigate about four times the amount of green house gas emissions and non-renewable energy input compared to maize-biogas. Soil erosion, which can be entirely avoided with PV, exceeds soil renewal rates roughly 20-fold on maize fields. Regarding the overall Eco-indicator 99 (H) score under most favourable assumptions for the maize–biogas route, PV has still a more than 100% higher potential to mitigate environmental burden. At present, the key advantages of biogas are its price and its availability without intermittence. In the long run, and with respect to more efficient land use, biogas might preferably be produced from organic waste or manure, whereas PV should be integrated into buildings and infrastructures.
The importance of intact ecosystems for human-wellbeing as well as the dependence on functions and services they provide is undoubted. But still neither the costs of ecosystem degradation nor the benefits from ecosystem functions and services appear on socio-economic balance sheets when development takes place. Consequently overuse of natural resources is socio-economically promoted by conventional resource management policies and external effects (externalities), equally positives and negatives, remain unregarded. In this context the potential of payments for hydrological ecosystem services as a political instrument to foster sustainable natural resource use, and rural development shall be investigated. This paper introduces the principle concept of such payments, presents a case study from Nicaragua and highlights preliminary effects of the application of this instrument on natural resource use and development.
This study analyzes the usefulness of an attitude-based target group approach in predicting the ecological impact of mobility behavior. Based on a survey of 1,991 inhabitants of three large German cities, constructs derived from an expanded version of the Theory of Planned Behavior were used to identify distinct attitude-based target groups. Five groups were identified, each representing a unique combination of attitudes, norms, and values. The groups differed significantly from each other with regard to travel-mode choice, distances traveled, and ecological impact. In comparison with segmentations based on sociodemographic and geographic factors, the predictive power of the attitude-based approach was higher, especially with regard to the use of private motorized modes of transportation. The opportunities and limits of reducing the ecological impact of mobility behavior on the basis of an attitude-based target group approach are discussed.
Life Cycle Assessment (LCA) has matured over the past decades and become part of the broader field of sustainability assessment. To strengthen LCA as a tool and eventually increase its usefulness for sustainability decision-making, it is argued that there is a need to expand the ISO LCA framework by integration and connection with other concepts and methods. This paper explores the potential options for deepening and broadening the LCA methodologies beyond the current ISO framework for improved sustainability analysis. By investigating several environmental, economic and social assessment methods, the paper suggests some options for incorporating (parts of) other methods or combining with other methods for broadening and deepening the LCA.
Scientization : putting global climate change on the scientific agenda and the role of the IPCC
(2010)
Since the 1970s, climate change has dominated the international scientific and political agenda. In particular, the foundation of the Intergovernmental Panel on Climate Change at the end of the 1980s played a major role for the further enhancement of efforts in the field of climate change sciences. However, to understand the interaction of the worldwide coordination of climate change sciences as well as the role of the Intergovernmental Panel on Climate Change and its consequences, it is worthwhile to take a look at the self-conception of the Intergovernmental Panel on Climate Change's tasks and work. This paper gives an idea of the history of international climate change science, its representation in public discourse and the role of the Intergovernmental Panel on Climate Change by comprehensively illustrating its tasks, organization and self-image. Furthermore, the article tries to argue that the hitherto accepted concept of science followed within this body fails to integrate the idea of scientific ethics. It can be concluded that the conception of science represented by the Intergovernmental Panel on Climate Change has heavily influenced worldwide attention to climate change, its becoming part of the political agenda as well as the ethical consequences.
For parabolic trough power plants using synthetic oil as the heat transfer medium, the application of solid media sensible heat storage is an attractive option in terms of investment and maintenance costs. One important aspect in storage development is the storage integration into the power plant. A modular operation concept for thermal storage systems was previously suggested by DLR, showing an increase in storage capacity of more than 100 %. However, in these investigations, the additional costs needed to implement this storage concept into the power plant, like for extra piping, valves, pumps and control had not been considered. These aspects are discussed in this paper, showing a decrease of levelized energy costs with modular storage integration of 2 to 3 %. In a Life Cycle Assessment (LCA) a comparison of an AndaSol-I type solar thermal power plant [1] with the original two-tank molten salt storage and with a "hypothetical" concrete storage shows an advantage of the concrete storage technology concerning environmental impacts. The environmental impacts of the “hypothetical” concrete based AndaSol-I decrease by 7 %, considering 1 kWh of solar electricity delivered to the grid. Regarding only the production of the power plant, the emissions decrease by 9.5 %.
New technologies can be the basis for resource-efficient products and services and thus create eco-innovations, either by creating new functionalities in existing or new application fields or by substituting existing technologies in existing or new application fields. In this paper, an overview over different technology fields, products and strategies with resource efficiency potential, such as nanotechnolo- gies, material science, manufacturing technologies, process technologies and cross-cutting issues, is presented. There is a special focus on applications from nanotechnology issuing, e.g. functional surfaces or new "smart" materials with special functionalities. Furthermore, it is shown how companies can use the method Resource Efficiency Technology Radar to identify and evaluate technolo- gies with resource efficiency in order to incorporate them into their development activities.
Preventing the worst consequences of climate change would require that GHG emissions be reduced to levels near zero by the middle of the century. To respond to such a daunting challenge, we need to rethink and redesign the currently highly energy-dependent infrastructures of industrial societies and particularly the urban infrastructures to become low- or even zero-carbon cities. Sustainable urban infrastructures need technology. In this paper focused on Western European Cities, we discuss a wide set of technologies in the fields of building, energy and transport infrastructures that can significantly contribute to a reduction of energy and/or GHG emissions and are already available or are in the pipeline. Based on the review of a recent study for the city of Munich, we then present how a mix of these technologies could reduce CO2-emissions by up to 90% for the metropolis of 1.3 million inhabitants and that this strategy could be economically attractive despite a high initial investment.
All of the residential buildings of a city like Munich could be entirely redesigned for EUR 200 per inhabitant annually, which is about one third of an average annual natural gas bill.
Natural gas makes an increasing contribution to the European Union's energy supply. Due to its efficiency and low level of combustion emissions this reduces greenhouse gas emissions compared to the use of other fossil fuels. However, being itself a potent greenhouse gas, a high level of direct losses of natural gas in its process chain could neutralise these advantages. Which effect will finally prevail depends on future economical as well as technical developments. Based on two different scenarios of the main influencing factors we can conclude that over the next two decades CH4 emissions from the natural gas supply chain can be significantly reduced, in spite of unfavourable developments of the supply structures. This, however, needs a substantial, but economically attractive investment into new technology, particularly in Russia.
Energy used in buildings is responsible for more than 40% of energy consumption and greenhouse gas (GHG) emissions of the EU and their share in cost-efficient GHG mitigation potentials is estimated to be even higher. In spite of its huge savings potential of up to 80%, achievements are very slow in the building sector and much stronger political action seems to be needed. One important step in this direction has been the recast of the Energy Performance of Buildings Directive (EPBD) in autumn 2009. However, strong national implementation including powerful packages of flanking measures seems to be crucial to really make significant progress in this important field. In order to directly improve political action, we provide a differentiated country-by-country bottom up simulation of residential buildings for the whole EU, Norway, Iceland, Croatia and Liechtenstein. The analysis provides a database of the building stock by construction periods, building types, as well as typical building sizes. It includes a simulation of the thermal quality and costs of the components of the building shell for new buildings as well as the refurbishment of the existing building stock. Based on this differentiated analysis, we show in detail what would be needed to accelerate energy savings in the building sector and provide a more precise estimate of the potentials to be targeted by particular policies. We demonstrate, e.g. that the potential of building codes set via the EPBD would be located mainly in those countries that already have quite stringent codes in place. We show as well the high relevance of accelerating refurbishments and re-investment cycles of buildings. By providing a clear estimate of the full costs related to such a strategy, we highlight a major obstacle to accelerated energy-efficient building renovation and construction.
Purpose - The Hot Spot Analysis developed by the Wuppertal Institute is a screening tool focussing on the demand of reliable sustainability-oriented decision-making processes in complex value chains identifying high priority areas ("hot spots") for effective measures in companies. This paper aims to focus on this tool.
Design/methodology/approach - The Hot Spot Analysis is a qualitative method following a cradle-to-cradle approach. With the examples of coffee and cream cheese hot spots of sustainability indicators throughout the entire life cycle are identified and evaluated with data from literature reviews and expert consultations or stakeholder statements. This paper focuses on the indicator resource efficiency as an example of how the methodology works.
Findings - The identified hot spots for coffee are the raw material procurement phase in terms of abiotic material, water and energy consumption, the production phase concerning biotic material and the energy consumption in the use phase. For cream cheese relevant hot spots appear in the raw material procurement phase in terms of biotic materials and water as well as biotic materials and energy consumption during the production phase.
Research limitations/implications - Life cycle analyses connected to indicators like resource efficiency need to be applied as consequent steps of a Hot Spot Analysis if a deeper level of analysis is eventually aimed at which is more cost and time intensive in the short term. The Hot Spot Analysis can be combined with other sustainability management instruments.
Practical implications - Research and management can be directed to hot spots of sustainability potential quickly which pays off in the long term.
Originality/value - The paper shows that companies can address sustainability potentials relatively cost moderately.
Die multilaterale Politik bekennt sich zum Zwei-Grad-Ziel, um den Klimawandel zu begrenzen. Sie stützt sich dazu explizit auf Empfehlungen "der Wissenschaft". Bemerkenswert ist, dass sie sich dabei nicht - was doch naheläge - auf das IPCC beruft. Dieses Gremium hat sich nämlich explizit versagt, "Werturteile" wie das Zwei-Grad-Ziel zu formulieren. Da die Politik aber nach solchen Urteilen verlangt, bedient sie sich pragma tisch an anderer Stelle - bei einer Wissenschaft, die nicht strikt zwischen Fakten und Werturteilen trennt. Letzteres sollte auch ein Kennzeichen einer Wissenschaft von der Nachhaltigkeit (sustainability science) sein.
Der (Flug-)Verkehr nimmt zu - auch in Zeiten des Klimawandels : wie kommt es zu diesem Paradox?
(2010)
Zum Flugverkehr als klimapolitischem "Ausreißer" wird zweierlei gefragt: 1. Nach dem zentralen Grund für die auf Expansion gerichtete Sonderstellung des (Flug-)Verkehrs; 2. Wie im konkreten Falle, bei der Erweiterung der Kapazität des Flughafens München, die klimapolitischen Randbedingungen marginalisiert werden.
A promising candidate that may follow conventional vehicles with internal combustion engines combines hydrogen from regenerative sources of energy, fuelcells and an electric drive train. For early fleets introduced the refuelling infrastructure needs to be in place at least to the extent of the vehicles operational reach. The question arises which strategies may help to keep initial hydrogen and infrastructure cost low? Industrial production, distribution and use of hydrogen is well-established and the volumes handled are substantial. Even though today's industrialhydrogen is not in tune with the long-term sustainable vision, hydrogen production and infrastructure already in place might serve as a nucleus for putting that vision into practice. This contribution takes stock of industrial production and use of hydrogen in North Rhine-Westphalia based on a recently finalized project. It demonstrates to which extent industrial hydrogen could be used for a growing number of vehicles and at which time additional capacity might need to be installed.
The Gulf countries are largely dependent on exporting oil and natural gas for their national budgets. They mainly use domestic fossil fuels for their domestic energy supply. In spite of favorable geographic conditions, especially for solar energy, renewable energies are still a niche application. Abu Dhabi, besides Dubai, the most important emirate in the United Arab Emirates (UAE), has now started a process of "transforming oil wealth into renewable energy leadership", and has set the long-term goal of a "transition from a 20th Century, carbon-based economy into a 21st Century sustainable economy." This article is a case study about "Masdar City", a planned carbon-neutral town in Abu Dhabi. The article describes the key characteristics of Masdar City, analyses the drivers behind the project, identifies the main actors for its implementation, and seeks obstacles to creation and development as well as the policy behind Masdar City. Finally, a first judgment of possible diffusion effects of the project is done.
Bahrain, Kuwait, Oman, Qatar, Saudi Arabia, and the United Arab Emirates are major oil and natural gas producing countries that make up the Gulf Cooperation Council. The six GCC countries fall in the top 25 countries of carbon dioxide emissions per capita and are perceived as the main actors blocking international climate change negotiations. The aim of this article is to discuss from a policy perspective the capacities of the GCC states to switch toward an ecological modernization of their energy sectors. At the beginning of the paper, I analyze the benefits of transforming oil wealth into funding for renewable energy and energy efficiency. After this, I discuss obstacles to such a transformation process based on the rentier states theory. Finally, I investigate governance of the GCC on all levels (international, regional, and local). The article shows that the GCC countries have recently adopted a more pro-active approach toward ecological modernization. This reorientation has not yet resulted in the development of consistent strategies and policies, however. The concluding assumption based on the concept of policy transfer is that pioneering projects such as Masdar City and innovative regulation like the green building code in Dubai will spread within the GCC.
In 1990 a sovereign wealth fund was founded in Norway in which the country invests surpluses from oil and gas industry sales. The fund is designed to secure the state's ability to act in a post-petroleum era. At the end of the 1990's the voice of Norwegian civil society insisted that the sovereign wealth fund should not only ensure intergenerational justice, but should also contribute to the implementation of values and norms of the present country. At the end of 2004 the parliament finally agreed upon ethical regulations for the investment of the sovereign wealth fund. Now the second largest sovereign wealth fund in the world only invests in businesses that adhere to those ethical regulations. In the present paper, I seek to illustrate the emergence and outcomes of this new development in the Norwegian sovereign wealth fund.
Renania del Norte-Westfalia (RNW) es el mayor estado federal (land) de la República Federal de Alemania. Hasta la década de 1970, la región del Rin-Ruhr, con una población de unos 12 millones de habitantes y una potente industria química, del carbón y del acero, se vio afectada por graves problemas de contaminación. En los años setenta, la protección medioambiental apareció en las agendas políticas nacionales e internacionales. Los gobiernos federales y el estatal lanzaron múltiples intervenciones legislativas y económicas para limpiar ríos, suelos y aire. Como resultado, surgió una ecoindustria muy competitiva. En este artículo, se resumen las características de las ecoindustrias y se describe el cambio estructural de la región del Ruhr. Asimismo, centrándose en el mesonivel y empleando los ejemplos de la gestión energética y la gestión municipal de residuos, se destacan los puntos fuertes y los puntos débiles de las políticas económicas regionales de clusters que apoyan las ecoindustrias en RNW.
Northrhine-Westphalia (NRW) is the largest land of the Federal Republic of Germany. Until the 1970ies the Ruhr-area with a population of about 12 million people and a strong coal, steel and chemical industry had been plagued with severe pollution. In the 1970ies environmental protection had emerged on the international and national policy agendas. The federal and regional government launched massive legislative and economic public interventions for cleaning-up rivers, soils and air. As a result, a highly competitive eco-industry emerged. The article outlines main features of ecoindustries, the structural change of the Ruhr area and regional economic cluster policies in support of eco-industries in NRW. It draws conclusions for eco-industry policy developing from end-of-pipe towards integrated preventive approaches.
Ein institutionelles Reformprogramm zur Förderung transdisziplinärer Nachhaltigkeitsforschung
(2010)
Die deutsche Politik orientiert sich in weiten Teilen an Nachhaltigkeit. Da erstaunt es, dass transdisziplinäre Nachhaltigkeitsforschung im Land kaum etabliert ist. Ein institutionelles Reformprogramm, das die besonderen Strukturbedingungen des deutschen Wissenschaftssystems berücksichtigt, vermag dies zu ändern.
Overviewing the European carbon (C), greenhouse gas (GHG), and non-GHG fluxes, gross primary productivity (GPP) is about 9.3 Pg yr-1, and fossil fuel imports are 1.6 Pg yr-1. GPP is about 1.25% of solar radiation, containing about 360 × 1018 J energy - five times the energy content of annual fossil fuel use. Net primary production (NPP) is 50%, terrestrial net biome productivity, NBP, 3%, and the net GHG balance, NGB, 0.3% of GPP. Human harvest uses 20% of NPP or 10% of GPP, or alternatively 1‰ of solar radiation after accounting for the inherent cost of agriculture and forestry, for production of pesticides and fertilizer, the return of organic fertilizer, and for the C equivalent cost of GHG emissions. C equivalents are defined on a global warming potential with a 100-year time horizon. The equivalent of about 2.4% of the mineral fertilizer input is emitted as N2O. Agricultural emissions to the atmosphere are about 40% of total methane, 60% of total NO-N, 70% of total N2O-N, and 95% of total NH3-N emissions of Europe. European soils are a net C sink (114 Tg yr−1), but considering the emissions of GHGs, soils are a source of about 26 Tg CO2 C-equivalent yr-1. Forest, grassland and sediment C sinks are offset by GHG emissions from croplands, peatlands and inland waters. Non-GHGs (NH3, NOx) interact significantly with the GHG and the C cycle through ammonium nitrate aerosols and dry deposition. Wet deposition of nitrogen (N) supports about 50% of forest timber growth. Land use change is regionally important. The absolute flux values total about 50 Tg C yr-1. Nevertheless, for the European trace-gas balance, land-use intensity is more important than land-use change. This study shows that emissions of GHGs and non-GHGs significantly distort the C cycle and eliminate apparent C sinks.
Global climate
(2010)
The fifteenth Conference of the Parties (COP 15) to the United Nations Framework Convention on Climate Change (UNFCCC) and the fifth Conference of the Parties serving as Meeting of the Parties to the Kyoto Protocol (CMP 5) took place on 7–18 December 2010 in Copenhagen. According to the "Bali Action Plan", the "roadmap" of the negotiations agreed at COP 13/CMP 3 in Bali in 2007, the Copenhagen conference was to deliver a comprehensive agreed outcome on the future climate regime. Meeting this deadline was of urgency not only because of the ever more alarming messages from climate science, but also because the first commitment period of the Kyoto Protocol expires in 2012. As ratification of a new agreement can be expected to take at least two years, a timely agreement on post-2012 emission targets is needed to prevent a "gap" after 2012. Expectations were high as more than 100 Heads of State and Government had announced their attendance and more than 40,000 participants had registered their names.
However, despite a record number of five preparatory meetings over the course of 2009, the fundamental differences between Parties proved to be too difficult to overcome. The main outcome of the conference, the "Copenhagen Accord", is only a political declaration, and even this declaration was not supported by all countries. In addition, Parties agreed to continue negotiations into 2010.
This article analyses the negotiations on the future of the international climate regime at the United Nations Climate Summit in Copenhagen. It also discusses key issues in the ongoing business of implementing the Climate Convention and the Kyoto Protocol. The article lays out the main issues at stake in the negotiations, contrasts divergences in interests amongst negotiating parties, and summarises the results achieved in Copenhagen. The report discusses these results in detail and concludes with an outlook on how the challenges ahead could be overcome.
Several energy scenario studies consider concentrated solar power (CSP) plants as an important technology option to reduce the world's CO2 emissions to a level required for not letting the global average temperature exceed a threshold of 2–2.4 °C. A global ramp up of CSP technologies offers great economic opportunities for technology providers as CSP technologies include highly specialised components. This paper analyses possible value creation effects resulting from a global deployment of CSP until 2050 as projected in scenarios of the International Energy Agency (IEA) and Greenpeace International. The analysis focuses on the economic opportunities of German technology providers since companies such as Schott Solar, Flabeg or Solar Millennium are among the leading suppliers of CSP technologies on the global market.
Renewable energy can become the major energy supply option in low-carbon energy economies. Disruptive transformations in all energy systems are necessary for tapping widely available renewable energy resources. Organizing the energy transition from non-sustainable to renewable energy is often described as the major challenge of the first half of the 21st century. Technological innovation, the economy (costs and prices) and policies have to be aligned to achieve full renewable energy potentials, and barriers impeding that growth need to be removed. These issues are also covered by IPCC's special report on renewable energy and climate change to be completed in 2010. This article focuses on the interrelations among the drivers. It clarifies definitions of costs and prices, and of barriers. After reviewing how the third and fourth assessment reports of IPCC cover mitigation potentials and commenting on definitions of renewable energy potentials in the literature, we propose a consistent set of potentials of renewable energy supplies.
Japan
(2010)
It is now widely recognized that effective communication and demand-side policies for alternative energy require sound knowledge of preferences and determinants of demand of the public and consumers. To date, public attitudes towards new transport technologies have been studied under very different conceptual frameworks. This paper gives an overview of the various conceptual frameworks and methodologies used, where four main approaches can be distinguished: general attitudinal surveys, risk perception studies, non-market economic valuation studies, and other approaches such as those based on semiotic theory. We then review the findings of the recent literature on acceptance, attitudes and preferences for hydrogen and fuelcell end-use technologies, focusing on vehicles. These studies are then contrasted with related research into alternative fuel vehicles. The paper finally discusses the main trends in research and avenues for further work in this field. We recommend, among other things, the use of approaches that build knowledge and familiarity with the technology prior to the exploration of attitudes, and the set up of studies that take a whole-systems perspective of hydrogen technologies and that look at hydrogen in the context of other competing clean technologies.