Open Access

The Russian natural gas industry is the world's largest producer and transporter of natural gas. This paper aims to characterize the methane emissions from Russian natural gas transmission operations, to explain projects to reduce these emissions, and to characterize the role of emissions reduction within the context of current GHG policy. It draws on the most recent independent measurements at all parts of the Russian long distance transport system made by the Wuppertal Institute in 2003 and combines these results with the findings from the US Natural Gas STAR Program on GHG mitigation options and economics. With this background the paper concludes that the methane emissions from the Russian natural gas long distance network are approximately 0.6% of the natural gas delivered. Mitigating these emissions can create new revenue streams for the operator in the form of reduced costs, increased gas throughput and sales, and earned carbon credits. Specific emissions sources that have cost-effective mitigation solutions are also opportunities for outside investment for the Joint Implementation Kyoto Protocol flexibility mechanism or other carbon markets.

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.

The 2011 Japanese earthquake and tsunami, and the consequent accident at the Fukushima nuclear power plant, have had consequences far beyond Japan itself. Reactions to the accident in three major economies Japan, the UK, and Germany, all of whom were committed to relatively ambitious climate change targets prior to the accident are examined. In Japan and Germany, the accident precipitated a major change of policy direction. In the UK, debate has been muted and there has been essentially no change in energy or climate change policies. The status of the energy and climate change policies in each country prior to the accident is assessed, the responses to the accident are described, and the possible impacts on their positions in the international climate negotiations are analysed. Finally, the three countries' responses are compared and some differences between them observed. Some reasons for their different policy responses are suggested and some themes, common across all countries, are identified. Policy relevance: The attraction of nuclear power has rested on the promise of low-cost electricity, low-carbon energy supply, and enhanced energy independence. The Fukushima accident, which followed the Japanese tsunami of March 2011, has prompted a critical re-appraisal of nuclear power. The responses to Fukushima are assessed for the UK, Germany, and Japan. Before the accident, all three countries considered nuclear as playing a significant part in climate mitigation strategies. Although the UK Government has continued to support nuclear new build following a prompt review of safety arrangements, Japan and Germany have decided to phase out nuclear power, albeit according to different timescales. The factors that explain the different decisions are examined, including patterns of energy demand and supply, the wider political context, institutional arrangements, and public attitudes to risk. The implications for the international climate negotiations are also assessed.

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.

Using natural gas for fuel releases less carbon dioxide per unit of energy produced than burning oil or coal, but its production and transport are accompanied by emissions of methane, which is a much more potent greenhouse gas than carbon dioxide in the short term. This calls into question whether climate forcing could be reduced by switching from coal and oil to natural gas. We have made measurements in Russia along the world's largest gas-transport system and find that methane leakage is in the region of 1.4%, which is considerably less than expected and comparable to that from systems in the United States. Our calculations indicate that using natural gas in preference to other fossil fuels could be useful in the short term for mitigating climate change.

Purpose - Iran as an energy-rich country faces many challenges in the optimal utilization of its vast resources. High rates of population and economic growth, a generous subsidies program, and poor resource management have contributed to rapidly growing energy consumption and high energy intensity over the past decades. The continuing trend of rising energy consumption will bring about new challenges as it will shrink oil export revenues, restraining economic activities. This calls for a study to explore alternative scenarios for the utilization of energy resources in Iran. The purpose of this paper is to model demand for energy in Iran and develop two business-as-usual and efficiency scenarios for the period 2005-2030. Design/methodology/approach - The authors use a techno-economic or end-use approach to model energy demand in Iran for different types of energy uses and energy carriers in all sectors of the economy and forecast it under two scenarios: business as usual (BAU) and efficiency. Findings - Iran has a huge potential for energy savings. Specifically, under the efficiency scenario, Iran will be able to reduce its energy consumption 40 percent by 2030. The energy intensity can also be reduced by about 60 percent to a level lower than the world average today. Originality/value - The paper presents a comprehensive study that models the Iranian energy demand in different sectors of the economy, using data at different aggregation levels and a techno-economic end-use approach to illuminate the future of energy demand under alternative scenarios.

Only three days after the beginning of the nuclear catastrophe in Fukushima, Japan, on 11 March 2011, the German government ordered 8 of the country's 17 existing nuclear power plants (NPPs) to stop operating within a few days. In summer 2011 the government put forward a law - passed in parliament by a large majority - that calls for a complete nuclear phase-out by the end of 2022. These government actions were in contrast to its initial plans, laid out in fall 2010, to expand the lifetimes of the country's NPPs. The immediate closure of 8 NPPs and the plans for a complete nuclear phase-out within little more than a decade, raised concerns about Germany's ability to secure a stable supply of electricity. Some observers feared power supply shortages, increasing CO2-emissions and a need for Germany to become a net importer of electricity. Now - a little more than a year after the phase-out law entered into force - this paper examines these concerns using (a) recent statistical data on electricity production and demand in the first 15 months after the German government's immediate reaction to the Fukushima accident and (b) reviews the most recent projections and scenarios by different stakeholders on how the German electricity system may develop until 2025, when NPPs will no longer be in operation. The paper finds that Germany has a realistic chance of fully replacing nuclear power with additional renewable electricity generation on an annual basis by 2025 or earlier, provided that several related challenges, e.g. expansion of the grids and provision of balancing power, can be solved successfully. Already in 2012 additional electricity generation from renewable energy sources in combination with a reduced domestic demand for electricity will likely fully compensate for the reduced power generation from the NPPs shut down in March 2011. If current political targets will be realised, Germany neither has to become a net electricity importer, nor will be unable to gradually reduce fossil fuel generated electricity. Whether the reduction in fossil fuel use will be sufficient to adequately contribute to national greenhouse gas mitigation targets significantly depends on an active policy to promote electricity savings, continuous efforts to increase the use of renewables and a higher share of natural gas (preferably used in combined heat and power plants) in fossil fuel power generation.

In recent decades, better data and methods have become available for understanding the complex functioning of cities and their impacts on sustainability. This review synthesizes the recent developments in concepts and methods being used to measure the impacts of cities on environmental sustainability. It differentiates between a dominant trend in research literature that concentrates on the accounting and allocation of greenhouse gas emissions and energy use to cities and a reemergence of studies that focus on the direct and indirect material and resource flows in cities. The methodological approaches reviewed may consider cities as either producers or consumers, and all recognize that urban environmental impacts can be local, regional, or global. As well as giving an overview of the methodological debates, we examine the implications of the different approaches for policy and the challenges these approaches face in their application on the field.

The Paris Agreement calls on all nations to pursue efforts to contribute to limiting the global temperature increase to 1.5 °C above pre-industrial levels. However, due to limited global, regional and country-specific analysis of highly ambitious GHG mitigation pathways, there is currently a lack of knowledge about the transformational changes needed in the coming decades to reach this target. Through a meta-analysis of mitigation scenarios for Germany, this article aims to contribute to an improved understanding of the changes needed in the energy system of an industrialized country. Differentiation among six key long-term energy system decarbonization strategies is suggested, and an analysis is presented of how these strategies will be pursued until 2050 in selected technologically detailed energy scenarios for Germany. The findings show, that certain strategies, including the widespread use of electricity-derived synthetic fuels in end-use sectors as well as behavioral changes, are typically applied to a greater extent in mitigation scenarios aiming at high GHG emission reductions compared to more moderate mitigation scenarios. The analysis also highlights that the pace of historical changes observed in Germany between 2000 and 2015 is clearly insufficient to adequately contribute to not only the 1.5 °C target, but also the 2 °C long-term global target.

Nach einer langen Phase der Stabilität ist die Stromwirtschaft in den vergangenen 15 Jahren stark in Bewegung geraten. Mit der Liberalisierung stand zunächst der Wechsel von Gebietsmonopolen hin zu wettbewerblich organisierten Erzeuger- und Verbrauchermärkten an. Derzeit findet ein ganz ähnlicher Umbruch statt, der vom Übergang von konventioneller hin zu erneuerbarer Stromerzeugung gekennzeichnet ist. Aber sind die Paradigmen der einzelnen Phasen miteinander vereinbar und hat jede für sich noch immer ihre Daseinsberechtigung, oder ist hier eine Modifizierung notwendig? Das Strommarktdesign der Zukunft kann nicht auf einem leeren Blatt entworfen, sondern es müssen bestehende Strukturen berücksichtigt werden. Gleichzeitig ist die Frage zu beantworten, ob die Wahl zwischen regulatorischen oder marktbasierten Ansätzen sich auch anhand der mit ihnen möglichen Präzision der Steuerung unterscheidet.