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- Stoffströme und Ressourcenmanagement (38) (remove)
Dieser Beitrag stellt Ressourcenproduktivität als Kernstrategie vor. Schließlich kann sie nicht nur als Entschlackungskur fungieren, sondern auch als Innovationsmotor. Darüber hinaus wird ein Vorschlag zu einer internationalen Konvention für ein nachhaltiges Ressourcenmanagement gemacht, das vorhandene Verzerrungen reduzieren und zur Prävention von Ressourcenkonflikten beitragen soll. Erforderlich ist eine Sichtweise, bei der Material-, Energie-, Umwelt- und Technologieaspekte einerseits und internationale Entwicklungsaspekte andererseits integriert betrachtet werden. Schließlich geht es nicht um Rohstoffe als solche, sondern um ihre Funktion für menschliche Bedürfnisbefriedigung und Wohlstand. Nötig ist ein Paradigmenwechsel, in dem ein reines Angebotsdenken - welche Rohstoffmengen werden benötigt und wie können sie beschafft werden - zugunsten einer Systemperspektive überwunden wird.
Vor dem Hintergrund des Klimawandels und der Verknappung fossiler Ressourcen haben nachwachsende Rohstoffe in den letzten Jahren an Bedeutung gewonnen. Insbesondere die Bioenergie hat durch staatliche Fördermaßnahmen viel Aufmerksamkeit erfahren. Mit der Ausweitung der energetischen Nutzung von Biomasse sollen Beiträge zum Klimaschutz durch die Vermeidung von Treibhausgasen geleistet, die Versorgungssicherheit soll durch Ersatz der knapper werdenden fossilen Ressourcen erhöht und der ländliche Raum gestärkt werden. Die selben Argumente lassen sich auch für die stoffliche Nutzung von Biomasse heranziehen. Auch wenn diese etwas aus dem Blickfeld der energiebezogenen Diskussion geraten ist, kann hier in den nächsten Jahren ein erhebliches Marktwachstum erwartet werden. Biomasse als erneuerbare Ressource kann in Land- und Forstwirtschaft aber nur begrenzt bereitgestellt werden. Dies gilt umso mehr, als bestimmte Nachhaltigkeits-Anforderungen eingehalten werden müssen. Der zu erwartenden Nachfragesteigerung für nachwachsende Rohstoffe (Nawaro) steht damit eine limitierte Verfügbarkeit entgegen. Aus dieser leitet sich die Forderung nach einer möglichst effizienten Verwertung ab. In diesem Zusammenhang fällt immer häufiger der Begriff der Kaskadennutzung von Nawaro als möglicher Lösungsansatz. Dieses Konzept kann im Wesentlichen als eine Hintereinanderschaltung von (mehrfacher) stofflicher und energetischer Nutzung desselben Rohstoffs gesehen werden und schafft so eine Verbindung von Material- und Energiesektor. Das Prinzip der Kaskadennutzung ist damit ein Ansatz zur Steigerung der Rohstoffeffizienz von nachwachsenden Rohstoffen und zur Optimierung der Flächennutzung. Das Ziel des vorliegenden Berichts ist es, die Option "Kaskadennutzung" strategisch, differenziert und ganzheitlich zu beleuchten. Im Rahmen der Projektarbeit sind daher Anforderungen an eine nachhaltige Kaskadennutzung von Nawaro abgeleitet und Schlussfolgerungen zu deren Ausgestaltung gezogen worden, um die Potenziale von Biomasse hochwertig und erfolgreich zu nutzen.
This paper presents the strategy for a large EU-funded Integrated Project: EXIOPOL ("A New Environmental Accounting Framework Using Externality Data and Input-Output Tools for Policy Analysis"), with special attention for its part in environmentally extended (EE) input-output (IO) analysis. The project has three principal objectives: (a) to synthesize and further develop estimates of the external costs of key environmental impacts for Europe; (b) to develop an EE IO framework for the EU-27 in aglobal context, including as many of these estimates as possible, to allow for the estimation of environmental impacts (expressed as LCA themes, material requirement indicators, ecological footprints or external costs) of the activities of different economic sectors, final consumption activities and resource consumption; (c) to apply the results of the work to external costs and EE I-O for illustrative policy questions.
The paper aims to shed light on the methodological challenges of GHG monitoring at local level and to give an overview on current practices. Questions addressed are as follows: How do the methodologies which underlie different GHG inventory tools differ? What are the critical variables explaining differences between inventories? Can different GHG inventory tools be compatible - and/or interoperable - and under which conditions? The first section discusses methodological challenges related to the formation of local GHG inventories. Rather than giving a comprehensive overview on methodological problems, this section mainly highlights some of the central methodological challenges posed by local GHG inventories. This overview identifies critical variables and clarifies concepts that are necessary for the understanding of the subsequent analysis. In section two, some of the most advanced GHG inventory tools are analysed and the most important differences between these tools are highlighted. The paper concludes that the methodologies are not consistent. Local GHG inventories can thus hardly be compared. The paper gives research and policy recommendations towards greater comparability and sketches the requirements of an international protocol on urban GHG inventories.
Economics of Knowledge
(2009)
The study "A Green New Deal for Europe" consists of two basic elements: Firstly it aims to cope with the economic crisis through intensive measures in order to systematically stimulate the eco-industries, to create jobs and to boost economic recovery. Secondly it aims at establishing the foundation for a green modernisation of the European economy. The study examines existing EU strategies policies and programs concerning their suitability to implement the Green New Deal. It proposes exemplary measures in the field of energy, mobility and resource use. The study has been compiled by the Wuppertal Institute on behalf of the Greens/European Free Alliance (EFA) Group in the European Parliament.
The global land area required to meet the German consumption of agricultural products for food and non-food use was quantified, and the related greenhouse gas (GHG) emissions, particularly those induced by land-use changes in tropical countries, were estimated. Two comprehensive business-as-usual scenarios describe the development corridor of biomass for non-food use in terms of energetic and non-energetic purposes. In terms of land use, Germany was already a net importer of agricultural land in 2004, and the net additional land required by 2030 is estimated to comprise 2.5–3.4 Mha. This is mainly due to biofuel demand driven by current policy targets. Meeting the required biodiesel import demand would result in an additional GWP of 23–37 Tg of CO2 equivalents through direct and indirect land-use changes. Alternative scenario elements outline the potential options for reducing Germany's land requirement, which reflect future global per capita availability.
Globale Rohstoffpolitik ist Umwelt-, Entwicklungs-, Sicherheits-, Innovations- und Wirtschaftspolitik in einem. Der Band analysiert aktuelle Herausforderungen globaler Rohstoffpolitik. Zugleich entwickelt er Perspektiven für ein globales Ressourcenmanagement auf der Grundlage verbesserter Transparenz und internationaler Verrechtlichung.
Sustainable management of natural resources is a crucial element for a sustainable development, but also a precondition for economic growth. The book analyses raw materials supply and resource use in a global context. The contributions present state-of-the art results and perspectives on the availability of resources. They discuss factors such as demand from emerging and other countries as well as critical shortage of some materials together with the resulting consequences for economies. It also gives new views and perspectives on the sustainable growth in ermerging economies and examines the possibilities and experiences concerning the decoupling of resource use from economic growth. Moreover, it offers cross-country comparisons with emphasis on emerging countries. A key focus is placed on China regarding its domestic energy, climate and resource policy but also its developing foreign policy in Africa.
On the one hand, biofuels may provide environmental and social benefits, for instance, when local communities in developing countries are supplied with power and process energy from oil producing plants, in particular when they are grown on land which is not suited for food production. On the other hand, the ongoing expansion of large scale energy farming for transport biofuels can lead to various environmental and social problems. Corn production for ethanol (additive to petrol) for instance resulted in nutrient pollution of the Mississippi basin and the Gulf of Mexico. The growing demand of transport biofuels in Europe can only be met by increasing imports. This contributes to the conversion of grasslands, savannahs and forests in the tropics, losses of biodiversity and additional green house gas emissions. Even if the use of biomass for other purposes, for instance, the combined production of electricity and heat usually provides a better greenhouse gas balance than transport biofuels, energy cropping remains problematic for various reasons. Whereas, when biomass is used for material purposes first, and the energy is recovered from the subsequent waste, a multiple dividend can be gained. The authors address a number of measures for improvement. They also recommend that in view of the complex circumstances of biofuel production and application, current policy mandates and targets for biofuels should be reconsidered. Biomass policies need to be integrated into a broader perspective of sustainable resource management.
Sustainable Resource Management is the result of longlasting exhaustive research by the Wuppertal Institute. Looking at material flows, industrial and societal metabolism and their implications for the economy, this new book provides radical perspectives on how the global economy should use natural resources in intelligent ways that maximise well-being without destroying lifesupporting ecosystems. It presents a vision of the future and the fundamental elements necessary for the sustainable management of the Earth's resources. It argues that the need to manage the use of our natural resources at a sustainable level can be shaped into a great opportunity for innovation and for new institutions to govern change.
A model of the use of the platinum group metals (PGMs) platinum, palladium, and rhodium in Europe has been developed and combined with a model of the environmental pressures related to PGM production. Compared to the base case presented in Part I of this pair of articles, potential changes in PGM production and use are quantified with regard to cumulative and yearly environmental impacts and PGM resource use, for the period 2005–2020. Reducing sulfur dioxide (SO2) emissions of PGM producer Norilsk Nickel could cut the cumulative SO2 emissions associated with the use of PGMs in Europe by 35%. Cleaner electricity generation in South Africa could reduce cumulative SO2 emissions by another 9%. Increasing the recycling rate of end-of-life catalytic converters to 70% in 2020 could save 15% of the cumulative primary PGM input into car catalysts and 10% of the SO2 emissions associated with PGM production. In 2020, PGM requirements and SO2 emissions would be, respectively, 40% and 22% lower than the base case. Substituting palladium for part of the platinum in diesel catalysts, coupled with a probable palladium price increase, could imply 15% more cumulative SO2 emissions if recycling rates do not increase. A future large-scale introduction of fuel cell vehicles would require technological improvements to significantly reduce the PGM content of the fuel cell stack. The basic design of such vehicles greatly influences the vehicle power, a key parameter in determining the total PGM requirement.