Description: The earth's capacity to absorb greenhouse gases is ultimately a critical limiting factor in the handling of metals. The fact that the demand for metals far exceeds their secondary production is extremely problematic at this point. Nevertheless, metals are crucial for climate protection and energy system transformation. Examples are the rare earth metal neodymium used in high-performance permanent magnets in wind turbines, the alkali metal lithium as the most important component in batteries, or the metal tellurium used in thin-film solar cells to generate solar power. It is therefore essential to promote the aspects of resource efficiency and to strengthen the critical role of metals in national and European policy programs. Next to a global solution, a European solo effort with predominantly market-based instruments and the effects of committed behaviour by civil society in the European Union (EU), show that the EU can make a considerable contribution to sustainable development on its own. Thus, a comprehensive approach is needed for sustainable metal management in the sense of a circular economy on the European level fostering sustainable production and consumption pathways. But, this need and the special role of metals are not seen in the current debate about resources in society and politics. Due to the fact that in public perception, metallic raw materials are often discussed as less urgent than energy or polymer raw materials, this article aims to highlight the critical role of metals. Further, the objective of this contribution is to show which prerequisites exist for the development and establishment of a holistic metal management and where political strategies have to start. Challenges needed to be overcome to achieve such a holistic metal strategy and management are highlighted. In particular, the role of the metal industry, circular product design and labelling and corresponding indicator systems is examined. In addition, the special role of digitalisation is being worked out. Finally, conclusions are drawn and shown which aspects have to be considered for a holistic metal strategy and management.

Description: The role of cities in mitigating GHG emissions and thus tackling global warming has gained importance over the last years.Many cities have developed climate action plans, primarily to achieve long-term "low-carbon" mitigation goals set by national governments or (inter)national agreements. A mere adoption of high level targets, however, raises the question whether these targets are applicable for cities with very different framework conditions. We argue that it is crucial to understand the socio-economic, geophysical, spatial, infrastructural and political framework of a city - a broad approach, which is generally missing in climate action plans. Thus, determining drivers and barriers for future development paths is neglected by local policies, which leads to a gap between ambition (target) and reality (implementation). We exemplarily examine this hypothesis for the shrinking city of Oberhausen (Germany). Oberhausen, located in the Ruhr area,is a typical old industrial region, which has seen a decline of its industrial basis over the last decades. We analysed historical data and developed scenarios until 2030. Both show a significant decrease in CO2 emissions. A closer look, however, reveals that the reduction is primarily due to the economic transformation (less manufacturing, more service industry, accompanied by a decrease in population) and general energy efficiency developments following the implementation of national and EU policies. Although the city has implemented–and will further implement - many instruments and policies to reduce CO2 emissions, local barriers such as unemployment, low rents, low income, high per capita debts, etc. dramatically reduce the city's capacity for action. The results show that Oberhausen's emission reductions do not reflect active energy policies but are mainly driven by an economic decline. To reach ambitious reduction targets, however, the city needs to be enabled to take action in achieving appropriate and reasonable targets.

Description: Over the years Shell has produced a number of scenario studies on key energy issues. These have included studies on important energy consumption sectors such as passenger cars and commercial vehicles (lorries and buses) and the supply of energy and heat to private households, as well as studies on the state of and prospects for individual energy sources and fuels, including biofuels, natural gas and liquefied petroleum gas. Shell has been involved in hydrogen production as well as in research, development and application for decades, with a dedicated business unit, Shell Hydrogen. Now, in cooperation with the Wuppertal Institute in Germany, Shell has conducted a study on hydrogen as a future energy source. The study looks at the current state of hydrogen supply path- ways and hydrogen application technologies and explores the potential and prospects for hydrogen as an energy source in the global energy system of tomorrow. The study focuses on the use of hydrogen in road transport and specifically in fuel cell electric vehicles (FCEVs), but it also examines non-automotive resp. stationary applications.

Description: Sustainable consumption policies affect households differently, in particular when they are confronted with limitations on income, time or freedom of movement (e.g. driving to work). And although it is possible to assess either the average or individual material footprint (per capita or via surveys), we lack methods to describe different types of households, their lifestyles and footprints in a representative manner. We explore possibilities to do so in this article. Our interest lies in finding an applicable method that allows us to describe the footprint of households regarding their socio-demographic characteristics but also find the causes consumption behaviour. This type of monitoring would enable us to tailor policies for sustainable consumption that respect people's needs and restrictions.

Description: Energy efficiency improvements have numerous benefits/impacts additional to energy and greenhouse gas savings, as has been shown and analysed e.g. in the 2014 IEA Report on "Multiple Benefits of Energy Efficiency". This paper presents the Horizon 2020-project COMBI ("Calculating and Operationalising the Multiple Benefits of Energy Efficiency in Europe"), aiming at calculating the energy and non-energy impacts that a realisation of the EU energy efficiency potential would have in 2030. The project covers the most relevant technical energy efficiency improvement actions and estimates impacts of reduced air pollution (and its effects on human health, eco-systems/crops, buildings), improved social welfare (incl. disposable income, comfort, health, productivity), saved biotic and abiotic resources, and energy system, energy security, and the macroeconomy (employment, economic growth and public budget). This paper explains how the COMBI energy savings potential in the EU 2030 is being modelled and how multiple impacts are assessed. We outline main challenges with the quantification (choice of baseline scenario, additionality of savings and impacts, context dependency and distributional issues) as well as with the aggregation of impacts (e.g. interactions and overlaps) and how the project deals with them. As research is still ongoing, this paper only gives a first impression of the order of magnitude for additional multiple impacts of energy efficiency improvements may have in Europe, where this is available to date. The paper is intended to stimulate discussion and receive feedback from the academic community on quantification approaches followed by the project.

Description: Wasserstoff ist ein Element, das viel Beachtung erhält: Es gilt als Basis einer nachhaltigen Energiezukunft. Allerdings ist Wasserstoff nicht allein, er konkurriert mit anderen Energien und ihren Nutzungstechnologien. Es stellt sich die Frage, ob Wasserstoff im globalen Energiesystem der Zukunft eine tragende Rolle spielen kann bzw. wird. Shell ist schon seit Jahrzehnten in der Wasserstoff-Forschung und -Entwicklung aktiv. In Zusammenarbeit mit dem Wuppertal Institut hat Shell jetzt eine Energieträger-Studie erstellt, die sich mit dem aktuellen Stand und den langfristigen Perspektiven der Wasserstoffnutzung, insbesondere für Energie- und Verkehrszwecke, befasst. Die Shell Wasserstoff-Studie diskutiert zunächst natürliche Vorkommen, Eigenschaften sowie historische Sichtweisen des Elements Wasserstoff. Anschließend werden aktuelle sowie künftige Verfahren und Ausgangsstoffe zur Erzeugung von Wasserstoff untersucht; dabei werden die Herstellungspfade in puncto Energieaufwand, Treibhausgasemissionen sowie Bereitstellungskosten miteinander verglichen. Weiterhin werden Fragen der Wasserstofflogistik untersucht. Dazu gehören zum einen heutige und künftige Speichermethoden, zum anderen die verschiedenen Transportoptionen und ihre jeweiligen Vorzüge einschließlich Fragen der Transportökonomie. Es folgt eine Darstellung der unterschiedlichen Nutzungsmöglichkeiten von Wasserstoff. Unterschieden wird zwischen stofflichen und energetischen Nutzungen. Die Analyse der energetischen Wasserstoffnutzung fokussiert auf die Brennstoffzelle - und nicht auf Wärmekraftprozesse. Auf der Anwenderseite werden energetische stationäre Anwendungen für die Back-up-Stromerzeugung sowie die Hausenergieversorgung - und diese einschließlich Wirtschaftlichkeit - untersucht. Den Schwerpunkt der Studie bilden (auto)mobile Wasserstoffanwendungen. Hierfür werden zunächst technologischer Stand und Perspektiven mobiler Anwendungen - von der Raumfahrt über Material Handling bis hin zum Pkw - erörtert. Anschließend wird die Wirtschaftlichkeit von wasserstoff-betriebenen Brennstoffzellen-Pkw (FCEV) mit Hilfe eines vereinfachten Autokosten-Vergleichs analysiert. Es schließt sich eine Diskussion des Aufbaus einer Wasserstoff-Tankstelleninfrastruktur für den Straßenverkehr an. Abschließend werden in Anlehnung an das ambitionierte 2DS-Wasserstoffszenario der Internationalen Energieagentur mögliche Auswirkungen von Brennstoffzellen-Pkw auf Kraftstoffverbrauch und Treibhausgasemissionen in ausgewählten Regionen bis 2050 diskutiert.