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- Stoffströme und Ressourcenmanagement (31) (remove)
Ziel dieser Studie ist es, einen aktuellen Überblick über den Stand der Recyclingwirtschaft in Deutschland zu geben. Der Fokus liegt dabei vor allem auf den Marktprozessen, die bereits heute ökonomische Anreize zur Schließung von Stoffkreisläufen geben, bzw. auf spezifischen Hemmnissen, die genau solchen Entwicklungen im Wege stehen.
Aufbauend auf der Analyse spezifischer Hemmnisse für einzelne Abfallfraktionen (rechtliche und institutionelle Hemmnisse, Marktmacht, Informationsdefizite etc.) leitet die Studie verschiedene Instrumente und handlungsorientierte Ansätze ab, die zu einer Verbesserung der Kreislaufführung beitragen könnten; dabei kann Deutschland auch von bestehenden Best-Practice-Ansätzen im Ausland profitieren. Dazu gehören unter anderem der verstärkte Einsatz ökonomischer Instrumente, Maßnahmen zur verstärkten Integration von Abfallwirtschaft und Produktionssektor, Urban Mining Konzepte, internationale Vereinbarungen zum Rohstoffrecycling sowie Green Tech Funds.
A desirable future critically depends on our ability to ensure the supply of key resources while simultaneously respecting planetary boundaries. This paper looks at the potential implications of living within the "safe operating space" for people, business and the economy. It develops a positive vision of the future based on three pillars: a safe and fair use of global resources, a sustainable society, and a transformed economy. We review and build on recent sustainability visions to develop a holistic reflection on what life in 2050 could look like, and explore the key changes in the economy needed to get there. In particular we show that resource efficiency requires a systemic shift in values, innovation, governance and management regimes. We present a bold vision for Europe underlined by indicators and targets, explore transition challenges to getting there and conclude with a list of key policies needed for overcoming challenges and reaching the vision.
Global warming, the overall extraction of minerals and the expansion of cultivated land for biomass harvest are growing globally. These "Big Three" represent key environmental pressures which may lead to a continuous degradation of the living environment, if not controlled at levels with acceptable low risk. The situation is complex, because countries and regions consume products which require resources such as minerals and land in various parts of the world. Nevertheless, it is possible to measure the global resource use which is associated with the domestic consumption. In order to inform policies at the national and supranational level whether it may be necessary to adjust the incentive framework for industry and households, reference data are needed to compare the status quo of their countries with what may be deemed acceptable at a global level. This chapter outlines a rationale for the derivation of possible long-term targets for total material consumption of abiotic materials (TMCabiot) and global land use for crops (GLUcropland). The indicated targets are expressed in tentative per capita values which may serve as a first orientation and basis for further debate and research.
The current flow of carbon for the production, use, and waste management of polymer-based products is still mostly linear from the lithosphere to the atmosphere with rather low rates of material recycling. In view of a limited future supply of biomass, this article outlines the options to further develop carbon recycling (C-REC). The focus is on carbon dioxide (CO2) capture and use for synthesis of platform chemicals to produce polymers. CO2 may be captured from exhaust gases after combustion or fermentation of waste in order to establish a C-REC system within the technosphere. As a long-term option, an external C-REC system can be developed by capturing atmospheric CO2. A central role may be expected from renewable methane (or synthetic natural gas), which is increasingly being used for storage and transport of energy, but may also be used for renewable carbon supply for chemistry. The energy input for the C-REC processes can come from wind and solar systems, in particular, power for the production of hydrogen, which is combined with CO2 to produce various hydrocarbons. Most of the technological components for the system already exist, and, first modules for renewable fuel and polymer production systems are underway in Germany. This article outlines how the system may further develop over the medium to long term, from a piggy-back add-on flow system toward a self-carrying recycling system, which has the potential to provide the material and energy backbone of future societies. A critical bottleneck seems to be the capacity and costs of renewable energy supply, rather than the costs of carbon capture.