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Im folgenden Beitrag untersuchen wir die Bürgerbeteiligung im Projekt InnovationCity Ruhr - Modellstadt Bottrop. Im Frühjahr 2010 hat der Initiativkreis Ruhr einen Wettbewerb ausgerufen, bei dem die "Klimastadt der Zukunft" gefunden werden sollte. Ausschlaggebend für den Sieg der Ruhrgebietsstadt war das vorgelegte Konzept, welches Gesellschaft, Wirtschaft und Wissenschaft verbindet. Ziel von InnovationCity Ruhr ist es die CO2-Emmissionen in der Stadt bis 2020 zu halbieren und somit eine Vorbildfunktion zur sozial-ökologischen Transformation für das gesamte Ruhrgebiet einzunehmen. Anhand der (Zwischen-) Ergebnisse zweier Untersuchungen (Best 2013; Roose 2014) werden wir veranschaulichen, wie die Bottroper Bevölkerung die Beteiligungsmöglichkeiten im Projekt wahrnimmt. Darüber hinaus decken wir Hemmschwellen auf und geben Empfehlungen zu einer verbesserten Aktivierung der und breiten Beteiligung durch die Bürgerinnen und Bürger.
Dem Thema Natur in der Stadt näherten sich die Teilnehmer(innen) eines Seminars zur Politischen Ökologie durch theoretische Beiträge und praktische Erkundungen. Sie richteten einen kritischen Blick auf das Vorfindliche, das als Natur im weiteren Sinne identifiziert werden kann, um historische und funktionale Bezüge erkennbar zu machen.
Urban energy systems have been commonly considered to be socio-technical systems within the boundaries of an urban area. However, recent literature challenges this notion in that it urges researchers to look at the wider interactions and influences of urban energy systems wherein the socio-technical sphere is expanded to political, environmental and economic realms as well. In addition to the inter-sectoral linkages, the diverse agents and multilevel governance trends of energy sustainability in the dynamic environment of cities make the urban energy landscape a complex one. There is a strong case then for establishing a new conceptualisation of urban energy systems that builds upon these contemporary understandings of such systems. We argue that the complex systems approach can be suitable for this. In this paper, we propose a pilot framework for understanding urban energy systems using complex systems theory as an integrating plane. We review the multiple streams of urban energy literature to identify the contemporary discussions and construct this framework that can serve as a common ontological understanding for the different scholarships studying urban energy systems. We conclude the paper by highlighting the ways in which the framework can serve some of the relevant communities.
Access to sustainable and affordable energy services is a crucial factor in reducing poverty in developing countries. In particular, small-scale and community-based renewable energy projects are recognized as important forms of development assistance for reaching the energy poor. However, to date only a few empirical evaluations exist which analyze and compare the impact of these projects on local living conditions and their sustainability ex-post implementation.
To better understand the impacts and the conditions that influence sustainability of these projects, the research presented in this paper evaluated 23 local development projects post implementation. By applying an standardized evaluation design to a cross-sectional sample in terms of renewable energy sources (solar, wind, biomass, hydro), user needs (electricity, food preparation, lighting, productive uses), community management models, finance mechanisms and geographical locations, the review results provide valuable insights on the underlying conditions that influence the success or failure of these small-scale local energy interventions. The empirical evidence suggests that the sustainability of small-scale energy implementations (≤100 kW) in developing countries is determined by the same factors, independent of the socio-cultural, political and ecological context. These findings allow to better predict the long-term success of small sustainable energy projects in developing countries, this can help to improve project designs and increase the certainty for future investment decisions.
New energy technologies may fail to make the transition to the market once research funding has ended due to a lack of private engagement to conclude their development. Extending public funding to cover such experimental developments could be one way to improve this transition. However, identifying promising research and development (R&D) proposals for this purpose is a difficult task for the following reasons: Close-to-market implementations regularly require substantial resources while public budgets are limited; the allocation of public funds needs to be fair, open, and documented; the evaluation is complex and subject to public sector regulations for public engagement in R&D funding. This calls for a rigorous evaluation process. This paper proposes an operational three-staged decision support system (DSS) to assist decision-makers in public funding institutions in the ex-ante evaluation of R&D proposals for large-scale close-to-market projects in energy research. The system was developed based on a review of literature and related approaches from practice combined with a series of workshops with practitioners from German public funding institutions. The results confirm that the decision-making process is a complex one that is not limited to simply scoring R&D proposals. Decision-makers also have to deal with various additional issues such as determining the state of technological development, verifying market failures or considering existing funding portfolios. The DSS that is suggested in this paper is unique in the sense that it goes beyond mere multi-criteria aggregation procedures and addresses these issues as well to help guide decision-makers in public institutions through the evaluation process.
Conventional new buildings in OECD countries with a history of building codes save about 50 % of energy compared to average buildings in the building stock. This improvement, however, is not enough to create a building standard with low lifetime costs nor to reach long-term climate protection targets. Much higher energy savings can already be achieved through proven high-efficiency building concepts bringing net economic benefits among other advantages.
A strategic approach to integrated building design is the key to achieving these high-energy savings at low or no extra cost in residential buildings. In our paper we describe the "Easy Efficiency Approach", which can reduce primary energy consumption by 40 to 60 % compared to conventional new building standards, or by 70% to 80% when compared to the primary energy consumption of the existing building stock, and should be regarded as the minimum. This strategy focuses on low-cost options, mainly passive options. Although it can already significantly reduce energy consumption, this first step will not be sufficient to reach long-term climate protection goals. It is thus necessary to implement and support what we call an "Advanced Efficiency Approach", with savings up to 90% , as compared to new building standards, as soon as possible to avoid lock-in effects. Further improvements, especially through the active use of renewable energies, reduce the net primary energy demand to 0 % and beyond.
According to the chosen strategy clearly defined energy performance ranges, with reference to possible savings, for different climate zones worldwide are given. In verifying this approach simulations with BAT (Best Available Technologies) buildings of different types (single family, multi family, high rise) were carried out in close cooperation with project partners. This data has also been verified through an empirical database of built examples both for energy consumption as well their economic soundness.
The Paris Agreement introduces long-term strategies as an instrument to inform progressively more ambitious emission reduction objectives, while holding development goals paramount in the context of national circumstances. In the lead up to the twenty-first Conference of the Parties, the Deep Decarbonization Pathways Project developed mid-century low-emission pathways for 16 countries, based on an innovative pathway design framework. In this Perspective, we describe this framework and show how it can support the development of sectorally and technologically detailed, policy-relevant and country-driven strategies consistent with the Paris Agreement climate goal. We also discuss how this framework can be used to engage stakeholder input and buy-in; design implementation policy packages; reveal necessary technological, financial and institutional enabling conditions; and support global stocktaking and increasing of ambition.
Given large potentials of the MENA region for renewable energy production, transitions towards renewables-based energy systems seem a promising way for meeting growing energy demand while contributing to greenhouse gas emissions reductions according to the Paris Agreement at the same time. Supporting and steering transitions to a low-carbon energy system require a clear understanding of socio-technical interdependencies in the energy system as well as of the principle dynamics of system innovations. For facilitating such understanding, a phase model for renewables-based energy transitions in MENA countries, which structures the transition process over time through the differentiation of a set of sub-sequent distinct phases, is developed in this article. The phase model builds on a phase model depicting the German energy transition, which was complemented by insights about transition governance and adapted to reflect characteristics of the MENA region. The resulting model includes four phases ("Take-off renewables", "System integration", "Power to fuel/gases”, "Towards 100% renewables”), each of which is characterized by a different cluster of innovations. These innovations enter the system via three stages of development which describe different levels of maturity and market penetration, and which require appropriate governance. The phase model has the potential to support strategy development and governance of energy transitions in MENA countries in two complementary ways: it provides an overview of techno-economic developments as orienting guidelines for decision-makers, and it adds some guidance as to which governance approaches are suitable for supporting those developments.
This article reviews the literature on the past cost dynamics of various renewable, fossil fuel and nuclear electricity generation technologies. It identifies 10 different factors which have played key roles in influencing past cost developments according to the literature. These 10 factors are: deployment-induced learning, research, development and demonstration (RD&D)-induced learning, knowledge spillovers from other technologies, upsizing, economies of manufacturing scale, economies of project scale, changes in material and labour costs, changes in fuel costs, regulatory changes, and limits to the availability of suitable sites. The article summarises the relevant literature findings for each of these 10 factors and provides an overview indicating which factors have impacted on which generation technologies. The article also discusses the insights gained from the review for a better understanding of possible future cost developments of electricity generation technologies. Finally, future research needs, which may support a better understanding of past and future cost developments, are identified.
The production of commodities by energy-intensive industry is responsible for 1/3 of annual global greenhouse gas (GHG) emissions. The climate goal of the Paris Agreement, to hold the increase in the global average temperature to well below 2 °C above pre-industrial levels while pursuing efforts to limit the temperature increase to 1.5 °C, requires global GHG emissions reach net-zero and probably negative by 2055-2080. Given the average economic lifetime of industrial facilities is 20 years or more, this indicates all new investment must be net-zero emitting by 2035-2060 or be compensated by negative emissions to guarantee GHG-neutrality. We argue, based on a sample portfolio of emerging and near-commercial technologies for each sector (largely based on zero carbon electricity & heat sources, biomass and carbon capture, and catalogued in an accompanying database), that reducing energy-intensive industrial GHG emissions to Paris Agreement compatible levels may not only be technically possible, but can be achieved with sufficient prioritization and policy effort. We then review policy options to drive innovation and investment in these technologies. From this we synthesize a preliminary integrated strategy for a managed transition with minimum stranded assets, unemployment, and social trauma that recognizes the competitive and globally traded nature of commodity production. The strategy includes: an initial policy commitment followed by a national and sectoral stakeholder driven pathway process to build commitment and identify opportunities based on local zero carbon resources; penetration of near-commercial technologies through increasing valuation of GHG material intensity through GHG pricing or flexible regulations with protection for competitiveness and against carbon leakage; research and demand support for the output of pilot plants, including some combination of guaranteed above-market prices that decline with output and an increasing requirement for low carbon inputs in government procurement; and finally, key supporting institutions.
Securing universal access to electricity by using renewable energy sources is technically feasible. A broad range of technological options, which can meet almost any requirements, are available. Solutions can comprise the connection of users to large distribution networks (on-grid solutions) or the application of power supply systems that can operate autonomously (off-grid and mini-grid solutions). This brochure concentrates on the latter solutions; technologies for large-scale distribution are not covered.
Nigeria is Africa's largest economy and home to approximately 10% of the un-electrified population of Sub-Saharan Africa. In 2017, 77 million Nigerians or 40% of the population had no access to affordable, reliable and sustainable electricity. In practice, diesel- and petrol-fuelled back-up generators supply the vast majority of electricity in the country. In Nigeria's nationally-determined contribution (NDC) under the Paris Agreement, over 60% of the greenhouse gas emissions (GHG) reductions are foreseen in the power sector. The goal of this study is to identify and critically examine the pathways available to Nigeria to meet its 2030 electricity access, renewables and decarbonization goals in the power sector. Using published data and stakeholder interviews, we build three potential scenarios for electrification and growth in demand, generation and transmission capacity. The demand assumptions incorporate existing knowledge on pathways for electrification via grid extension, mini-grids and solar home systems (SHS). The supply assumptions are built upon an evaluation of the investment pipeline for generation and transmission capacity, and possible scale-up rates up to 2030. The results reveal that, in the most ambitious Green Transition scenario, Nigeria meets its electricity access goals, whereby those connected to the grid achieve a Tier 3 level of access, and those served by sustainable off-grid solutions (mini-grids and SHS) achieve Tier 2. Decarbonization pledges would be surpassed in all three scenarios but renewable energy goals would only be partly met. Fossil fuel-based back-up generation continues to play a substantial role in all scenarios. The implications and critical uncertainties of these findings are extensively discussed.
Heating behavior of households is key for reducing domestic energy demand and mitigating climate change. Recently, various technical devices have been developed, providing households with feedback on their heating behavior and supporting energy conservation behavior.
The impact of such devices on overall energy consumption depends on (1) the impact of a device within a household, (2) the diffusion of devices to other households and the number of adopters, and (3) the diffusion of the induced behavioral change beyond these households. While the first two processes are currently established in assessments of sustainable household devices, we suggest that adding behavior diffusion is essential when assessing devices that explicitly target behavioral change. We therefore propose an assessment framework that includes all three processes. We implement this framework in an agent-based model by combining two existing simulation models to explore the effect of adding behavior diffusion. In three simulation experiments, we identify two mechanisms by which behavior diffusion (1) spreads the effect of such devices from adopters to non-adopters and (2) increases the average speed of behavioral change of households. From these results we conclude that behavior diffusion should be included in assessments of behavior-changing feedback devices.
Diesen Technologien wird für das Energiesystem, bei einem zunehmenden Ausbau der fluktuierenden regenerativen Leitenergieträger Wind und Sonneneinstrahlung als zentrale Flexibilitätsoption sowie zur Dekarbonisierung der Industrie - Bereitstellung von Wasserstoff und Kohlenwasserstoffen -, eine Schlüsselrolle zukommen. Wie die bisherigen Erfahrungen mit anderen Energieinfrastrukturen, z. B. Freileitungen oder Windkraftanlagen, zeigen, stellt eine breite gesellschaftliche Akzeptanz einen wesentlichen Erfolgsfaktor für die großflächige Diffusion und Transformation dar. Entsprechend ist die gesellschaftliche Einbettung auch bei der Planung von PtX-Strategien frühzeitig zu beachten.
Akzeptanz von industriellem CCS in Nordrhein-Westfalen : Empfehlungen für Politik und Industrie
(2023)
Für die Landesregierung Nordrhein-Westfalen (NRW) ist die industriell genutzte Kohlenstoffabscheidung und -speicherung (engl. industrial carbon capture and storage, kurz iCCS) ein zentraler Baustein für den Übergang zu einer klimaneutralen Industrie bis 2045. Dafür braucht es aber eine breite gesellschaftliche Akzeptanz - zumal Pläne zur CO2-Abscheidung bei Kohlekraftwerken vor über zehn Jahren schon einmal an mangelnder gesellschaftlicher Akzeptanz gescheitert sind. In diesem In Brief haben die Autor*innen die Ergebnisse von zwei durchgeführten Akzeptanzstudien zu iCCS in NRW zusammengefasst und diskutieren, welche Handlungsempfehlungen sich daraus ergeben.
In the debate about the transformation process towards sustainability manifold eco social economic concepts are discussed. Most of them lay claim to democracy, to processes of inclusion of all who are affected. But do alternative concepts automatically lead to democracy, overcoming hierarchies, power and exclusion? Based on this question, the article discusses two eco social concepts: Vorsorgendes Wirtschaften and Small new Social Contracts. It throws the light on traps like repressive or instrumental forms of inclusion and ends with three clues for a transformative democratic way to sustainability.
Soll der Staat oder der Markt der Hauptakteur im Prozess einer "Großen Transformation" der Gesellschaft sein? Und: Welcher Staat und welcher Markt? Deutlich wird, dass eine Transformation Richtung Nachhaltigkeit nicht gelingen kann, wenn alte Rationalitäts muster - wie die vom starken Staat und vom selbstregulieren den Markt - fortbestehen. Dagegen muss ein demokratischer Prozess stehen, der auf den Fähigkeiten der Bürger(innen) basiert und der emanzipatorische und herrschafts kritische Bewegungen stärkt.
The Greens / European Free Alliance Group of the European Parliament contracted Wuppertal Institute in collaboration with Energiaklub to develop scientifically sound, comprehensive, alternative, and sustainable long term energy scenarios for Hungary, which cover potential development paths till 2030 and 2050. The scenarios developed deliver information about the costs and long-term effects of different energy choices for Hungary as well as credible information on potential benefits of greening the energy mix. As a result, the study aims to provide policy makers with better evidence for making informed, prudent and forward-thinking decisions in this field.
The target of zero emissions sets a new standard for industry and industrial policy. Industrial policy in the twenty-first century must aim to achieve zero emissions in the energy and emissions intensive industries. Sectors such as steel, cement, and chemicals have so far largely been sheltered from the effects of climate policy. A major shift is needed, from contemporary industrial policy that mainly protects industry to policy strategies that transform the industry. For this purpose, we draw on a wide range of literatures including engineering, economics, policy, governance, and innovation studies to propose a comprehensive industrial policy framework. The policy framework relies on six pillars: directionality, knowledge creation and innovation, creating and reshaping markets, building capacity for governance and change, international coherence, and sensitivity to socio-economic implications of phase-outs. Complementary solutions relying on technological, organizational, and behavioural change must be pursued in parallel and throughout whole value chains. Current policy is limited to supporting mainly some options, e.g. energy efficiency and recycling, with some regions also adopting carbon pricing, although most often exempting the energy and emissions intensive industries. An extended range of options, such as demand management, materials efficiency, and electrification, must also be pursued to reach zero emissions. New policy research and evaluation approaches are needed to support and assess progress as these industries have hitherto largely been overlooked in domestic climate policy as well as international negotiations.
The European Union (EU) has established that the goal of achieving climate neutrality by 2050 as a key driver of innovation and growth for industry and the economy in the EU. In addition to offering great opportunities, this also poses considerable challenges for the European economy and, for the most part, for basic industries, which are particularly emission-intensive and face strong international competition.
An integrated climate and industry strategy is of central importance to protecting the climate, since the production of steel, cement, basic chemicals, glass, paper, and other materials in the EU and worldwide accounts for roughly one fifth of total greenhouse gas emissions. Even in a greenhouse gas-neutral future, we will not be able to fully eliminate our need for these materials. At the same time, it is particularly challenging to produce these materials without creating emissions given the state of technology and the necessary infrastructures. This applies above all to the question of how large amounts of green energy, including electricity and hydrogen, can be produced at competitive prices. Analyses show that despite the considerable costs involved in process changeover, the costs of transforming the raw materials industry are acceptable to society as a whole, given that the additional costs usually only increase the price of the end products by a few percentage points. However, in the case of crude steel or cement, the price would increase by between one third and 100 per cent. Since almost all raw materials manufacturers face strong global market competition, in most cases they are not able to bankroll the investments in climate-neutral production and the required energy infrastructure without outside support.
This paper outlines an integrated climate industrial policy package that allows the EU to utilise its existing technological leadership in many of these industries to build a greenhouse gas-neutral raw materials industry.
Roadmaps for India's energy future foresee that coal power will continue to play a considerable role until the middle of the 21st century. Among other options, carbon capture and storage (CCS) is being considered as a potential technology for decarbonising the power sector. Consequently, it is important to quantify the relative benefits and trade-offs of coal-CCS in comparison to its competing renewable power sources from multiple sustainability perspectives. In this paper, we assess coal-CCS pathways in India up to 2050 and compare coal-CCS with conventional coal, solar PV and wind power sources through an integrated assessment approach coupled with a nexus perspective (energy-cost-climate-water nexus). Our levelized costs assessment reveals that coal-CCS is expensive and significant cost reductions would be needed for CCS to compete in the Indian power market. In addition, although carbon pricing could make coal-CCS competitive in relation to conventional coal power plants, it cannot influence the lack of competitiveness of coal-CCS with respect to renewables. From a climate perspective, CCS can significantly reduce the life cycle GHG emissions of conventional coal power plants, but renewables are better positioned than coal-CCS if the goal is ambitious climate change mitigation. Our water footprint assessment reveals that coal-CCS consumes an enormous volume of water resources in comparison to conventional coal and, in particular, to renewables. To conclude, our findings highlight that coal-CCS not only suffers from typical new technology development related challenges - such as a lack of technical potential assessments and necessary support infrastructure, and high costs - but also from severe resource constraints (especially water) in an era of global warming and the competition from outperforming renewable power sources. Our study, therefore, adds a considerable level of techno-economic and environmental nexus specificity to the current debate about coal-based large-scale CCS and the low carbon energy transition in emerging and developing economies in the Global South.
Die Ökodesign-Richtlinie (Richtlinie 2009/125/EG des Europäischen Parlaments und des Rates vom 21. Oktober 2009 zur Schaffung eines Rahmens für die Festlegung von Anforderungen an die umweltgerechte Gestaltung energieverbrauchsrelevanter Produkte) trat im Jahre 2005 in Kraft und wurde im Jahr 2009 revidiert und erweitert. Die Richtlinie zielt auf Verbesserungen des Designs energieverbrauchsrelevanter Produkte mit dem Ziel einer Reduktion der Umweltbelastungen unter Berücksichtigung aller Phasen des Produktlebenszyklusses. So sind bereits im Rahmen dieser Richtlinie beispielsweise Mindestenergieeffizienzanforderungen für bestimmte, auf dem europäischen Markt angebotene Geräte festgelegt worden, die von den Geräteherstellern und -importeuren eingehalten werden müssen.
Im Rahmen einer strategischen Partnerschaft zwischen Deutschland und Brasilien verfolgt die Zusammenarbeit für Nachhaltige Entwicklung (ZnE) das beidseitige Interesse, die Klima- und Biodiversitätsziele Brasiliens zu erreichen. Die Schwerpunkte der deutsch-brasilianischen Zusammenarbeit liegen auf den Bereichen Schutz und nachhaltige Nutzung der brasilianischen Tropenwälder und Erneuerbaren Energien und Energieeffizienz.
Im Schwerpunkt Energie kooperieren GIZ und KfW im Auftrag des BMZ seit 2009 mit brasilianischen Partnern. Die Zusammenarbeit beruht hierbei auf zentralen Hypothesen bezüglich zu erwartender Wirkungen im Hinblick auf die brasilianische Energiematrix, die Reduktion von Treibhausgasemissionen, die Schaffung geeigneter Rahmenbedingungen für erneuerbare Energien und Energieeffizienz, sowie die Entstehung neuer Märkte.
Ziel ist, mit den von deutscher Seite eingesetzten Ressourcen einen höchstmöglichen Mehrwert in den Bereichen Klimaschutz und Biodiversität zu erreichen. Ein zusätzlicher Aspekt der Zusammenarbeit ist die Förderung neuer Märkte für international wettbewerbsfähige Zweige der deutschen und europäischen Wirtschaft.
Inwieweit die unternommenen Maßnahmen zu den erwarteten Wirkungen beitragen, und wie sie weiterentwickelt werden könnten, wurde im Rahmen dieser Studie in Zusammenarbeit mit dem brasilianischen Partnerinstitut COPPE der Universität Rio de Janeiro anhand von ausgewählten Projekten aus verschiedenen Technologiebereichen untersucht. Diese Studie dient neben der kritischen Betrachtung von abgeschlossenen und laufenden Vorhaben der ZnE auch der künftigen strategischen Ausrichtung der technischen und finanziellen Zusammenarbeit zwischen Deutschland und Brasilien.
Diese Fallstudie untersuchte den durch die geringe Wettbewerbsfähigkeit des Steinkohlebergbaus ausgelösten Strukturwandel im Ruhrgebiet vom Ende der 1950er Jahre bis 2015. Mit Hilfe verschiedener qualitativer und quantitativer Methoden der empirischen Sozial- und Wirtschaftsforschung analysierte sie den Strukturwandelprozess und die in Reaktion auf diesen Prozess umgesetzte Strukturpolitik mit dem Ziel, dieses Wissen für zukünftige Strukturwandelprozesse in anderen (Kohle-)Regionen zur Verfügung zu stellen. Eine Diskursanalyse half zu erkennen, wer warum welche strukturpolitischen Ansätze unterstützte - und gibt damit Hinweise auf die mögliche Relevanz von Erfahrungen für andere Regionen.
Diese Fallstudie untersuchte den durch den Systemwechsel von der Plan- zur Marktwirtschaft ausgelösten Strukturwandel in der Lausitz im Zeitraum 1990-2015. Mit Hilfe verschiedener qualitativer und quantitativer Methoden der empirischen Sozial- und Wirtschaftsforschung analysierte sie den Strukturwandelprozess und die in Reaktion auf diesen Prozess umgesetzte Strukturpolitik mit dem Ziel, dieses Wissen für zukünftige Strukturwandelprozesse in anderen (Kohle-)Regionen zur Verfügung zu stellen. Eine Diskursanalyse half zu erkennen, wer warum welche strukturpolitischen Ansätze unterstützte - und gibt damit Hinweise auf die mögliche Relevanz von Erfahrungen für andere Regionen.
Direct air capture (DAC) combined with subsequent storage (DACCS) is discussed as one promising carbon dioxide removal option. The aim of this paper is to analyse and comparatively classify the resource consumption (land use, renewable energy and water) and costs of possible DAC implementation pathways for Germany. The paths are based on a selected, existing climate neutrality scenario that requires the removal of 20 Mt of carbon dioxide (CO2) per year by DACCS from 2045. The analysis focuses on the so-called "low-temperature" DAC process, which might be more advantageous for Germany than the "high-temperature" one. In four case studies, we examine potential sites in northern, central and southern Germany, thereby using the most suitable renewable energies for electricity and heat generation. We show that the deployment of DAC results in large-scale land use and high energy needs. The land use in the range of 167-353 km2 results mainly from the area required for renewable energy generation. The total electrical energy demand of 14.4 TWh per year, of which 46% is needed to operate heat pumps to supply the heat demand of the DAC process, corresponds to around 1.4% of Germany's envisaged electricity demand in 2045. 20 Mt of water are provided yearly, corresponding to 40% of the city of Cologne's water demand (1.1 million inhabitants). The capture of CO2 (DAC) incurs levelised costs of 125-138 EUR per tonne of CO2, whereby the provision of the required energy via photovoltaics in southern Germany represents the lowest value of the four case studies. This does not include the costs associated with balancing its volatility. Taking into account transporting the CO2 via pipeline to the port of Wilhelmshaven, followed by transporting and sequestering the CO2 in geological storage sites in the Norwegian North Sea (DACCS), the levelised costs increase to 161-176 EUR/tCO2. Due to the longer transport distances from southern and central Germany, a northern German site using wind turbines would be the most favourable.
Jordan's electricity system has and continues to experience considerable pressures for reform due to continuous increase of electricity demand combined with high dependency on imported fossil fuels and a partially subsidised electricity market. In this paper we use the transitions pathways to examine and analyse pressures on the regime in relation to plausible future developments of particular niches such as renewable energy technologies. Our analysis is methodologically distinct in that we explicitly identify mechanisms operating in the system and relate those to existing scenarios to assess future developments. Currently, we see future developments being sensitive to the actions of key regime actors.
The cement industry is one of the major energy consuming and CO2 emitting sectors in China. In 2010, 1,868 million tons of cement has been produced, which accounted for 56.1% of the world's total cement production. The 11th Five-Year Plan (FYP) (2006-2010) included policy measures for CO2 emission abatement in cement production. Based on the main governmental framework of CO2 mitigation policies at national level in the cement sector, key policies and technologies used during this period are identified and their effects on CO2 reduction are assessed. This paper calculates the reduction of CO2 emissions related to four main policies and technologies for efficient cement production in the 11th and the 12th FYP (2011-2015) with 2005 as a reference year. These are waste heat recovery, closing outdated facilities, substitution for clinker production and other technologies aiming to increase energy efficiency. Due to these measures, we estimate that a total CO2 emission reduction during the 11th FYP of 397 million tonnes could be saved, which is considerably different to 185.75 million tonnes estimated by Zeng (2008) and 303 million tonnes by the NDRC by using different calculation methods. Of the four technologies, the 4th group of energy efficiency increasing techniques was the most important policy and avoided the largest amount of CO2 emissions. Previous energy intensity reduction was mainly due to the outdated production closing and energy efficiency improving. Based on the assessment of technology performance, it appears that there is still a large emission reduction potential in cement production processes. The paper calculates this potential for the 12th FYP period (2011-2015) based on these four identified policy measures. The result is compared to the Chinese government targets in the 12th FYP and promising future CO2 mitigation policies and technologies are proposed, such as the use of alternative energy.
Analysis of the historical structural change in the German hard coal mining Ruhr area (case study)
(2022)
This case study examined the structural change in the Ruhr area caused by the low international competitiveness of German hard coal mining over the period from the late 1950s to 2015. It analysed the structural change process and the structural policies implemented as a reaction to this process with the objective to make this knowledge available for future structural change processes in other (coal) regions by deploying various qualitative and quantitative methods of empirical social and economic research. A discourse analysis helped to recognise who supported which structural policy approaches and why - and thus gives indications of the possible relevance of experiences for other regions.
This case study examined the structural change in Lusatia caused by the system change from a centrally planned economy to a market economy in the period 1990-2015. It analysed the structural change process and the structural policies implemented as a reaction to this process with the objective to make this knowledge available for future structural change processes in other (coal) regions by deploying various qualitative and quantitative methods of empirical social and economic research. A discourse analysis helped to recognise who supported which structural policy approaches and why - and thus gives indications of the possible relevance of experiences for other regions.
Das Vorhaben analysiert 1.) die Argumente verschiedener Positionen im Wachstumsdiskurs und formuliert eine idealtypische "vorsorgeorientierte Postwachstumsposition". Er präsentiert zudem Ursachen von Wirtschaftswachstum und identifiziert gesellschaftliche Bereiche, deren Funktion vom Wirtschaftswachstum abhängen könnte. Darüber hinaus werden Reformvorschläge diskutiert, um diese Wachstumsabhängigkeit zu verringern. Das Vorhaben untersucht 2.) die Relevanz der Postwachstumsdebatte für Ressourcenpolitik und eine entsprechende Instrumentierung. Außerdem werden 3.) konstitutive Kernelemente einer nachhaltigen (Postwachstums-)Gesellschaft bestimmt. Das Vorhaben setzt damit Impulse zur gesellschaftlichen Debatte über die Ausgestaltung und Instrumentierung von Transformationspfaden für "gesellschaftliches Wohlergehen innerhalb planetarer Grenzen".
The German government has set itself the target of reducing the country's GHG emissions by between 80 and 95% by 2050 compared to 1990 levels. Alongside energy efficiency, renewable energy sources are set to play the main role in this transition. However, the large-scale deployment of renewable energies is expected to cause increased demand for critical mineral resources. The aim of this article is therefore to determine whether the transformation of the German energy system by 2050 ("Energiewende") may possibly be restricted by a lack of critical minerals, focusing primarily on the power sector (generating, transporting and storing electricity from renewable sources). For the relevant technologies, we create roadmaps describing a number of conceivable quantitative market developments in Germany. Estimating the current and future specific material demand of the options selected and projecting them along a range of long-term energy scenarios allows us to assess potential medium- or long-term mineral resource restrictions. The main conclusion we draw is that the shift towards an energy system based on renewable sources that is currently being pursued is principally compatible with the geological availability and supply of mineral resources. In fact, we identified certain sub-technologies as being critical with regard to potential supply risks, owing to dependencies on a small number of supplier countries and competing uses. These sub-technologies are certain wind power plants requiring neodymium and dysprosium, thin-film CIGS photovoltaic cells using indium and selenium, and large-scale redox flow batteries using vanadium. However, non-critical alternatives to these technologies do indeed exist. The likelihood of supplies being restricted can be decreased further by cooperating even more closely with companies in the supplier countries and their governments, and by establishing greater resource efficiency and recyclability as key elements of technology development.
CCS is discussed in a broad sense throughout Europe. In this paper a cautious, conservative estimate of CO2 storage capacity for Germany and its neighbouring countries where CO2 emissions from Germany could possibly be stored (Netherlands, France, Denmark, Norway, UK and Poland) is presented. Such a lower limit calculation is necessary for orientation purposes for potential investors and political decision-makers.
Conservative CO2 sequestration capacity in deep saline aquifers for Germany is derived by the volumetric approach where parameters such as efficiency factor, CO2 density, porosity of the geological formation are of interest. It is assumed that every geological system is closed and thus an efficiency factor of 0.1 per cent (based on maximum pressure increase and total compressibility) for saline aquifers is applied. The capacity of German depleted oil and gas fields is based on cumulative recovery data and a sweep efficiency of 75 per cent. The storage capacity in the other considered countries, adjacent to Germany, are based on a critical review and adjustment of the results of the European reports JOULE II, GESTCO and GeoCapacity.
The conservative capacities for all countries together amount to 49 Gt CO2, from which Norway and the UK provide 36 Gt, all offshore in the North Sea. Compared to the emissions from large point sources in these countries during 40 years (47.6 Gt of CO2), a virtual balance is achieved. This can only be reached, if a large scale CO2 pipeline system is installed to connect these countries, especially Germany, to the large sinks in the North Sea. If additional restrictions like source-sink matching, acceptance issues and injection rates constraints are taken into account, the available storage space gets increasingly scarce.
On 26 January 2019, the Commission on Growth, Structural Change and Employment recommended that no more coal-fired power plants would be operated in Germany by 2038 at the latest. In this paper the Wuppertal Institute comments on the results of the Commission and makes recommendations for the current necessary steps for the climate and innovation policy in Europe, Germany and North Rhine-Westphalia.
Der Klimawandel stellt uns vor die globale Herausforderung, auf fossile Energieträger zu verzichten. Die erfolgreiche Transformation des Energiesystems ist eine wesentliche Voraussetzung für eine vollständige Reduktion der Treibhausgase. Eine solche Transformation kann nur gelingen, wenn der fundamental neue Charakter des Systems erfasst und im abgeleiteten Rückschluss daraus der passende Pfad eingeschlagen wird. Im Kern lässt sich dieser neue Charakter als ein defossilisiertes, auf regenerativen Energien basierendes Energiesystem beschreiben.
Die multilaterale Politik bekennt sich zum Zwei-Grad-Ziel, um den Klimawandel zu begrenzen. Sie stützt sich dazu explizit auf Empfehlungen "der Wissenschaft". Bemerkenswert ist, dass sie sich dabei nicht - was doch naheläge - auf das IPCC beruft. Dieses Gremium hat sich nämlich explizit versagt, "Werturteile" wie das Zwei-Grad-Ziel zu formulieren. Da die Politik aber nach solchen Urteilen verlangt, bedient sie sich pragma tisch an anderer Stelle - bei einer Wissenschaft, die nicht strikt zwischen Fakten und Werturteilen trennt. Letzteres sollte auch ein Kennzeichen einer Wissenschaft von der Nachhaltigkeit (sustainability science) sein.
Der Ergebnisbericht dokumentiert in Kapitel 2 die in diesem Forschungsvorhaben durchgeführten Arbeiten an dem von der TU Delft entwickelten agentenbasierten Strommarktmodell EMLab-Generation, das als Open-Source Modell konzipiert ist. Einen zentralen Aspekt bildet die Übertragung des Modells, das ursprünglich die beiden Regionen CWE (Central-Western- Europe) und UK umfasste, auf ein Modell mit den beiden Regionen Deutschland und Europa (ohne Deutschland), im Wesentlichen in den Grenzen der EU28. Diese Übertragung ist die Grundlage für die Untersuchung unterschiedlicher Fragestellungen hinsichtlich der zukünftigen Entwicklung des Strommarkts in Deutschland innerhalb des europäischen Verbundnetzes bei hohen Anteilen fluktuierender erneuerbarer Energien an der Stromerzeugung.
Nach der Darstellung der konkreten Zielsetzung und der Grundlagen des vorhandenen Modells werden im Hauptteil (Kapitel 2.3) die eigenen Modellierungsarbeiten (Datenaufbereitung, Modellierung und "lessons learned") beschrieben. Im Anschluss erfolgt eine kurze Darstellung einer noch in Erarbeitung befindlichen Masterarbeit zur Berücksichtigung von Risikoaspekten innerhalb des Investitionsalgorithmus' von EMLab-Generation, die sich aus dem internationalen ABM-Workshop als offene methodische Fragestellung von Strommarktmodellen ergeben hat (Kapitel 2.4). Kapitel 2.5 gibt eine kritische Einschätzung der erreichten Modellierungsergebnisse sowie weitere mögliche Anwendungen der neu konzipierten Modellregionen.
Kapitel 3 gibt anschließend einen Überblick über die in diesem Vorhaben durchgeführten gemeinsamen Workshops zwischen TU Delft und Wuppertal Institut sowie den internationalen Workshop, an dem fünf Forschungseinrichtungen aus Deutschland sowie die TU Delft erstmals ihre Erfahrungen mit ABM-Strommarktmodellierung austauschten und methodischen Forschungsbedarf aufarbeiteten.
Der Bericht schließt mit einer kurzen Zusammenfassung sowie einem Ausblick auf weitere Forschungsarbeiten, mit denen die im Rahmen dieser Anbahnungsmaßnahme begonnene Kooperation zwischen Wuppertal Institut und TU Delft fortgesetzt werden soll.
Das Forschungsvorhaben wurde im April des Jahres 2008 gestartet. Zentrales Ziel war die Entwicklung von Instrumenten zur Information, Kommunikation und Konsultation zur Deutschen Anpassungsstrategie an den Klimawandel. Weitere angestrebte Produkte waren die Entwicklung von interaktiven Tools für die Internetpräsenz www.anpassung.net des Kompetenzzentrums für Klimafolgen und Anpassung des Umweltbundesamtes (KomPass) und die Erarbeitung einer Broschüre mit nationalen und internationalen Praxisbeispielen der Anpassung.
Die direkte Abscheidung von Kohlenstoffdioxid (CO2) aus der Luft, das sogenannte Direct Air Capture (DAC), wird vermehrt als eine der Möglichkeiten zur Reduzierung von Treibhausgasen und damit der Begrenzung der Klimaerwärmung diskutiert. Vorteilhaft gegenüber anderen technischen Ansätzen zur Entnahme von atmosphärischen CO2 (Negativemissionstechnologien) ist die genaue Planbarkeit, die geringen Auswirkungen auf die Umwelt und die Ausgabe von CO2 in Reinform. Das CO2 kann anschließend dauerhaft gespeichert (Direct Air Capture and Sequestration) oder zur Erzeugung von bspw. synthetischen Brennstoffen (Direct Air Carbon Capture and Utilization) in Power-to-X-Routen (PtX) genutzt werden.
Ziel dieser Arbeit ist es, im Kontext der deutschen Klimaneutralitätsziele bis 2045 beispielhaft eine Auslegung von DAC-Anlagen in Deutschland zu untersuchen. Dabei werden die unterschiedlichen Ressourcenverbräuche (Energie, Wasser, Fläche) sowie Kosten und mögliche Einsparungen durch eine Abwärmenutzung dargestellt und verglichen.
Dabei soll diese Arbeit zur Beantwortung der folgenden Forschungsfragen beitragen:
Welche technologischen DAC-Ansätze sind für Deutschland realisierbar? Welche Mengen an CO2 müssen in Deutschland umgesetzt werden, um den Bedarf an Negativemission zu decken? Welcher Ressourcenverbrauch entsteht in Deutschland, wenn die betrachteten Fallstudien umgesetzt werden? Welchen Infrastrukturaufwand hat dies zur Folge? Ist eine Implementierung in den notwendigen Größenordnungen realisierbar, und welche Faktoren wirken hierbei beschränkend?
Für eine systematische Analyse wurden die DAC-, die PtX- und die elektrischen und Wärmeenergieerzeugungsanlagen modular für die Jahre 2020, 2030, 2040 und 2045 aufbereitet. Die Bezugsgrößen wurden so gewählt, dass sie dem DAC-Modul entsprechen. In vier Fallstudien wurden mögliche Kombinationsmöglichkeiten und Implementierungspfade bis 2045 zusammengestellt, analysiert und diskutiert. Es zeigt sich, dass ein großskaliger Einsatz von DAC in Deutschland realisierbar ist. Zentrale Herausforderungen ergeben sich allerdings aus dem hohen Flächen- und Energiebedarf. Der Flächenbedarf resultiert dabei vor allem aus den flächenintensiven erneuerbaren Energieerzeugern. Mit Fokus auf ertragreiche Standorte sind Nord- und Süddeutschland, mit Blick auf ihr Wind- bzw. Sonnenpotenzial, als vielversprechend bei der Implementierung der DAC- Technologie einzustufen. Eine Implementierung der DAC-Technologie mit dem Ziel der dauerhaften CO2-Speicherung ist an norddeutschen Küstengebieten im Vergleich zu Süddeutschland vorteilhafter. Die Installation der DAC-Technologie in Kombination mit der PtX-Route wird aufgrund des hohen elektrischen Energiebedarfs in Deutschland als nicht realisierbar eingeschätzt.
Die atompolitische Wende der Bundesregierung hatte zahlreichen Spekulationen und Befürchtungen Raum gegeben. Es wurde gemutmaßt, dass Deutschland zum Nettostromimporteur werden könnte, sollten die Kraftwerke (wie im Sommer 2011 beschlossen) dauerhaft außer Betrieb bleiben. Darüber hinaus nahm man an, dass die in Deutschland entfallende Stromerzeugung durch Kohlekraftwerke oder durch Importe aus französischen oder tschechischen Atomkraftwerken ersetzt würde und dass Strompreise sowie CO2-Emissionen deutlich ansteigen würden. Inzwischen liegen vorläufige Energiebilanzen und Marktdaten für das Jahr 2011 vor, die viele dieser Befürchtungen widerlegen. Der hier vorgenommene Ausblick auf die mögliche Entwicklung in den kommenden Jahren zeigt zudem, dass die Bilanz von 2011 keine Momentaufnahme sein muss, sondern dass der gegenüber 2010 wegfallende Kernenergiestrom - bilanziell gesehen - voraussichtlich bereits ab 2013 allein durch eine erhöhte regenerative Stromerzeugung kompensiert werden kann.