Ob die Rückführung von industriellen und gewerblichen Sekundärkunststoffen, das heißt von Abfällen bzw. von bereits wiederaufbereiteten Kunststoffrezyklaten, gelingen kann, ist von mehreren Faktoren wie insbesondere den spezifischen Materialeigenschaften, den Mengen, in denen sie anfallen, den aktuellen Marktpreisen (auch gegenüber Neuware) und auch der räumlichen Nähe von Sortier- bzw. Wiederaufbereitungsinfrastruktur abhängig. Trotz eigentlich guter Voraussetzungen für ein werkstoffliches Recycling, gelangen einzelne in Unternehmen anfallende Abfallchargen häufig in eine thermische Verwertung, weil sich ein Recycling wirtschaftlich nicht lohnt. Grund hierfür ist unter anderem, dass der Informationsaustausch zu den oben genannten Faktoren für Unternehmen häufig noch sehr mangelhaft ist.
Aktuell in Entwicklung befindliche digitale Plattformen und Applikationen sowie zugehörige Geschäfts- und Betreibermodelle, welche Kunststoffverarbeiter untereinander sowie Wertstofferzeuger und -verwerter vernetzen sollen, können künftig höhere Recyclingquoten ermöglichen und ökologische Einsparpotenziale heben.
Der Artikel führt Entwicklungen und Ergebnisse aktueller Forschungsprojekte zu solchen Vernetzungen zusammen, zeigt die aktuelle Situation des werkstofflichen Recyclings von industriellen und gewerblichen Kunststoffabfällen auf und beleuchtet welche Voraussetzungen für eine erfolgreiche Kreislaufführung von industriellen Kunststoffen gegeben sein müssen. Es wird insbesondere analysiert, in welcher Weise digitale Technologien und die durch sie erzielbare Informationstransparenz eine verbesserte Kreislaufwirtschaft bewirken können und in welcher Weise dies Wertschöpfungsnetzwerke räumlich beeinflussen kann.
The Digital Product Passport (DPP) is a concept of a policy instrument particularly pushed by policy circles to contribute to a circular economy. The preliminary design of the DPP is supposed to have product-related information compiled mainly by manufactures and, thus, to provide the basis for more circular products. Given the lack of scientific debate on the DPP, this study seeks to work out design options of the DPP and how these options might benefit stakeholders in a product's value chain. In so doing, we introduce the concept of the DPP and, then, describe the existing regime of regulated and voluntary product information tools focusing on the role of stakeholders. These initial results are reflected in an actor-centered analysis on potential advantages gained through the DPP. Data is generated through desk research and a stakeholder workshop. In particular, by having explored the role the DPP for different actors, we find substantial demand for further research on a variety of issues, for instance, on how to reduce red tape and increase incentives for manufacturers to deliver certain information and on how or through what data collection tool (e.g., database) relevant data can be compiled and how such data is provided to which stakeholder group. We call upon other researchers to close the research gaps explored in this paper also to provide better policy direction on the DPP.
In order to calculate the financial return of energy efficiency measures, a cost-benefit analysis (CBA) is a proven tool for investors. Generally, however, most CBAs for investors have a narrow focus, which is - simply speaking - on investment costs compared with energy cost savings over the life span of the investment. This only provides part of the full picture. Ideally, a comprehensive or extended CBA would take additional benefits as well as additional costs into account. The objective of this paper is to reflect upon integrating into a CBA two important cost components: transaction costs and energy efficiency services - and how they interact. Even though this concept has not been carried out to the knowledge of the authors, we even go a step further to try to apply this idea. In so doing, we carried out a meta-analysis on relevant literature and existing data and interviewed a limited number of energy experts with comprehensive experience in carrying out energy services. Even though data is hardly available, we succeeded in constructing three real-world cases and applied an extended CBA making use of information gathered on transaction costs and energy services costs. We were able to show that, despite these additional cost components, the energy efficiency measures are economically viable. Quantitative data was not available on how energy services reduce transaction costs; more information on this aspect could render our results even more positive. Even though empirical and conceptual research must intensify efforts to design an even more comprehensive CBA, these first-of-its-kind findings can counterargue those that believe energy efficiency is not worth it (in monetary terms) due to transaction costs or energy services costs. In fact, this is good news for energy efficiency and for those that seek to make use of our findings to argue in favor of taking up energy efficiency investments in businesses.
In the energy sector, few topics, if any, are more hyped than hydrogen. Countries develop hydrogen strategies to provide a perspective for hydrogen production and use in order to meet climate-neutrality goals. However, in this topical field the role of water is less accentuated. Hence, in this study, we seek to map the interrelations between the water and wastewater sector on the one hand and the hydrogen sector on the other hand, before reflecting upon our findings in a country case study. We chose the Hashemite Kingdom of Jordan because (i) hydrogen is politically discussed not least due to its high potentials for solar PV, and (ii) Jordan is water stressed - definitely a bad precondition for water-splitting electrolyzers. This research is based on a project called the German-Jordanian Water-Hydrogen-Dialogue (GJWHD), which started with comprehensive desk research mostly to map the intersectoral relations and to scope the situation in Jordan. Then, we carried out two expert workshops in Wuppertal, Germany, and Amman, Jordan, in order to further discuss the nexus by inviting a diverse set of stakeholders. The mapping exercise shows various options for hydrogen production and opportunities for planning hydrogen projects in water-scarce contexts such as Jordan.
Schon seit dem 19. Jahrhundert gilt Wasserstoff als Basis einer nachhaltigen Energiezukunft. Auch wenn sich noch keine kommerzielle Nutzung etabliert hat, sind Wasserstofftechnologien in den vergangenen Jahren deutlich weiterentwickelt worden. In Zusammenarbeit mit dem Wuppertal Institut hat Shell untersucht, welchen Beitrag Wasserstoff zu einer nachhaltigen Energieversorgung - vor allem im Verkehr - künftig leisten kann.
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.
The data centre industry (DCI) has grown from zero in the 1980s, to enabling 60% of the global population to be connected in 2021 via 7.2 million data centres. The DCI is based on a linear economy and there is an urgent need to transform to a Circular Economy to establish a secure supply chain and ensure an economically stable and uninterrupted service, which is particularly difficult in an industry that is comprised of ten insular subsectors. This paper describes the CEDaCI project which was established to address the challenge in this unique sector; this ground-breaking project employs a whole systems approach, Design Thinking and the Double Diamond methods, which rely on people/stakeholder engagement throughout. The paper reviews and assesses the impact of these methods and project to date, using quantitative and qualitative research, via an online sectoral survey and interviews with nine data centre and IT industry experts. The results show that the project is creating positive impact and initiating change across the sector and that the innovative output (designs, business models, and a digital tool) will ensure that sectoral transformation continues; the project methods and structure will also serve as an exemplar for other sectors.
Decarbonizing transportation in emerging economies will be one of the key challenges in global climate change mitigation efforts. In this paper, pathways are developed towards achieving a 1.5° degree scenario for land-transport for four emerging economies (Brazil, India, Kenya and Vietnam). The aim is to highlight the key opportunities and challenges for low-carbon transport in countries with rapidly growing mobility demand. The main focus of this paper is to reconcile actual and required emission reduction targets and develop plausible pathways to achieve these targets. The paper also identifies potential strategies and measures for these countries to follow these pathways. The analysis considers the contributions of "avoid" (cutting travel growth), "shift" (to lower CO2 modes) and "improve" (vehicle and fuel CO2 characteristics) interventions to decarbonisation scenarios. These scenarios aim to inform renewed Nationally Determined Contributions and shed light on the feasibility of deep decarbonisation pathways that would be in line with the Paris Agreement. Results from this study show that achieving 1.5DS would require dramatic changes in travel patterns, technology and fuels, and major intensification of current policy approaches. Decarbonization solutions will need to include greater use and investment of efficient modes, major shifts toward near-zero carbon fuels such as clean electricity, systems integration, modal shift and urban planning solutions. Although the socio-economic situations and national transport systems differ between the selected countries, some fairly similar strategies appear likely to be core to the mitigation effort, such as rapid growth in light- and heavy-duty vehicle electrification and investments in public transit systems.
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.
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 emissions resulting from agricultural production processes must be considered, mainly resulting from agricultural production processes, as fertilizer use, pesticide etc.
This paper 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 thus examining the current state of the art as well as new, large-scale plants, operated by industrial players. Not only technical and engineering aspects are taken into account here, but also the choice of feedstock which plays an important role as to the overall ecological evaluation of bio-methane.
The substrates evaluated in this paper - aside from maize - are rye, sorghum, whole-crop-silage from triticale and barley, and the innovative options of agricultural grass (Landsberger Gemenge, a mixture of hairy vetch (vicia villosa), crimson clover (trifolium incarnátum) and Italian ryegrass (lolium multiflorum)) as well as a combination of maize and sunflower.
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.
Die Bundesregierung verfolgt das ambitionierte Ziel einer Beschleunigung des Ausbaus der erneuerbaren Energien auf 80 % bis 2030 bzw. einer nahezu vollständig erneuerbaren Stromversorgung 2035. Im Zuge der avisierten Elektrifizierung anderer Sektoren wie Wärme und Mobilität im Rahmen der Sektorenkopplung nimmt die Bedeutung des Stromsektors weiter zu. Angesichts der aktuellen geopolitischen Umwälzungen und den sich abzeichnenden Knappheiten für fossiles Gas wird in einer Kurzstudie evaluiert, welchen Platz Biogas in einem langfristig zukunftsfähigen Energiesystem einnehmen kann.
Unvermeidbare Emissionen aus der Abfallbehandlung : Optionen auf dem Weg zur Klimaneutralität
(2022)
Auch die thermische Abfallbehandlung in Deutschland kann zu einem Baustein des klimaneutralen Wirtschaftens werden. Allerdings sind dafür noch verschiedene Voraussetzungen zu schaffen. Technisch sind neben den bereits bekannten weitere innovative Verfahren in der Entwicklung; nicht zu vernachlässigen ist zudem die anspruchsvolle Aufgabe des CO2-Handlings. Hier ist zum einen der Aufbau der benötigten Infrastruktur zu nennen. In Bezug auf die Nutzung des abgetrennten CO2 ist auch die Industrie gefragt, um sektorübergreifende, klimafreundliche Use-Cases und Geschäftsmodelle rund um CCU und die weitmöglichste Schließung von Kohlenstoffkreisläufen zu entwickeln. Entsprechende Regularien und Marktanreize sind politisch zu setzen.
Electronics containing growing quantities of high value and critical metals are increasingly used in automobiles. The conventional treatment practice for end-of-life vehicles (ELV) is shredding after de-pollution and partial separation of spare parts. Despite opportunities for resource recovery, the selective separation of components containing relevant amounts of critical metals for the purpose of material recycling is not commonly implemented. This article is aimed to contribute to recycling strategies for future critical metal quantities and the role of extended material recovery from ELVs. The study examines the economic feasibility of dismantling electronic components from ELVs for high value metal recycling. The results illustrate the effects of factors as dismantling time, labour costs and logistics on the economic potential of resource recovery from ELVs. Manual dismantling is profitable for only a few components at the higher labour costs in western/northern parts of Europe and applicable material prices, including the inverter for hybrid vehicles, oxygen sensor, side assistant sensor, distance and near distance sensors. Depending on the vehicle model, labour costs and current material prices, manual dismantling can also be cost-efficient for also some other such as the heating blower, generator, starter, engine and transmission control, start/stop motor, drive control, infotainment and chassis control.
Demand-side mitigation strategies have been gaining momentum in climate change mitigation research. Still, the impact of different approaches in passenger transport, one of the largest energy demand sectors, remains unclear. We couple a transport simulation model to an energy system optimisation model, both highly disintegrated in order to compare those impacts. Our scenarios are created for the case of Germany in an interdisciplinary, qualitative-quantitative research design, going beyond techno-economic assumptions, and cover Avoid, Shift, and Improve strategies, as well as their combination. The results show that sufficiency - Avoid and Shift strategies - have the same impact as the improvement of propulsion technologies (i.e. efficiency), which is reduction of generation capacities by one quarter. This lowers energy system transformation cost accordingly, but requires different kinds of investments: Sufficiency measures require public investment for high-quality public services, while efficiency measures require individuals to purchase more expensive vehicles at their own cost. These results raise socio-political questions of system design and well-being. However, all strategies are required to unleash the full potential of climate change mitigation.
In this paper, we aim to present a comprehensive analysis on the emerging phenomenon of distributed innovation in commons-based peer production (CBPP) platforms. Starting with the exploration of the widely held belief on value-creation confined to industrial settings, we raise several questions regarding the feasibility of, and a need for, an inclusive innovation process that can tap grassroots capacity into both traditional (industrial research and development) and emerging (peer-to-peer) innovation models to yield sustainable solutions. In particular, we explore the emergence and structuration of digital innovations in the maker movement, as it presents an alternative construct of innovation wherein access to and sharing of knowledge is predominantly distributed. With innovation outcomes often freely revealed, its very structuration could pose a principal challenge to our conceptualizations of value creation and competitive advantage in the current economic model. Drawing from responses received from 200 collaborative innovation platforms, six semi‐structured interviews focusing on socio-technical innovation cases, as well as four in-depth narrative interviews with maker turned entrepreneurs, we present a detailed analysis on the topology of network, typology of actors, as well as the underlying innovation ecosystem in CBPP networks in Germany. In doing so, we contribute to the conceptualization of peer-to-peer distributed innovations in collaborative platforms.
The current momentum in the electrification of the car fuels hope for a transition in mobility. However, electric vehicles have failed before and it is thus asked: What is the potential of e-mobility developing as a sustainable system innovation? In order to deal with this challenge analytically, a theoretical framework is developed: the concepts of transformative capacity of a new technology (do electric vehicles trigger "social" innovations, e.g. new business models or use patterns?) and system adaptability (how stable is the mobility regime?) are introduced and the issue of sustainability is discussed. This framework will be explored for the German innovation system for e-mobility. It can be shown that electric cars will only be successful when part of a system innovation and that the German innovation system is dominated by regime actors and thus potentially used as a way to fend off more substantial change.