Zukünftige Energie- und Industriesysteme
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Reaching net-zero in the chemical industry : a study of roadmaps for industrial decarbonisation
(2024)
Striving to mitigate climate change, the European Union has adopted net-zero greenhouse gas emissions as a target for 2050. In this paper, European chemical industry roadmaps from the past six years are assessed and compared to uncover how the industry envisions its role in the transition to net-zero emissions. The roadmaps are assessed in terms of ambition level, technology and feedstock strategies, investment needs and costs, agency and dependency on other actors, as well as timeline and concretion. Although net-zero pathways are often drawn out in the roadmaps, some also choose to emphasize and argue for less ambitious pathways with emission reductions of only 40-60 %. The roadmaps vary widely in terms of the importance they assign to mechanical and chemical recycling, switching to biogenic carbon and carbon dioxide as feedstock, electrification and hydrogen, and carbon capture and storage. A commonality though, is that low-tech or near-term mitigation pathways such as demand reduction, reuse or material efficiency are seldom included. High investment needs are generally highlighted, as well as the need for policy to create enabling conditions, whereas the agency and responsibility of the chemical industry itself is downplayed. Our analysis highlights that the chemical industry does not yet have a strong and shared vision for pathways to net-zero emissions. We conclude that such a future vision would benefit from taking a whole value chain approach including demand-side options and consideration of scope 3 emissions.
Green hydrogen and synthetic fuels are increasingly recognized as a key strategic element for the progress of the global energy transition. The Middle East and North Africa (MENA) region, with its large wind and solar potential, is well positioned to generate renewable energy at low cost for the production of green hydrogen and synthetic fuels, and is therefore considered as a potential future producer and exporter. Yet, while solar and wind energy potentials are essential, other factors are expected to play an equally important role for the development of green hydrogen and synthetic fuels (export) sectors. This includes, in particular, adequate industrial capacities and infrastructures. These preconditions vary from country to country, and while they have been often mentioned in the discussion on green hydrogen exports, they have only been examined to a limited extent. This paper employs a case study approach to assess the existing infrastructural and industrial conditions in Jordan, Morocco, and Oman for the development of a green hydrogen and downstream synthetic fuel (export) sector.
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.
The establishment of the Leveraging a Climate-neutral Society–strategic Research Network (LCS–RNet) (then named the International Research Network for Low Carbon Societies) was proposed at the Group of Eight (G8) Environment Ministers’ Meeting in 2008. Its 12th annual meeting in December 2021 focused on the discussion on how to transition into a just and sustainable society and how to reduce the risks associated with the transition. This requires comprehensive studies including on the concept of transition, pathways to net-zero societies and how to realise the pathways by collaborating with various stakeholders. This Special Feature provides new insights into sustainability science by linking the scientific knowledge with practical science for the transition through the exploration of studies presented at the annual meeting. Following the opening paper, "A challenge for sustainability science: can we halt climate change?", a wide range of topics were discussed, including practices for sustainable transformation in the Erasmus University, practices in industry, energy transition and international cooperation.
Deutschlands Haushalte werden, zu Beheizungszwecken, zu 70 % leitungsgebunden versorgt: 50 % mit Erdgas und 14 % mit Fernwärme; 5 % mit Elektrizität, davon je die Hälfte noch mit Nachtspeicherheizung, die andere Hälfte mit Wärmepumpen. So war es 2021. So wird es in Zukunft nicht sein, denn Erdgas ist ein Energieträger fossiler Herkunft. Dessen Nutzung geht in den nächsten beiden Jahrzehnten gen Null. Die Frage ist, was das für die Erdgasleitungen in Deutschland bedeutet.
The petrochemical industry is among the most relevant sectors from an economic, energetic and climate policy perspective. In Western Europe, production occurs in local chemical parks that form strongly connected and densely integrated regional clusters. This paper analyzes the structural characteristics of the petrochemical system in Germany and investigates three particularly distinct clusters regarding their challenges and chances for a transition towards climate-neutrality. For this, feedstock and energy supply, product portfolios and process integration as well as existing transformation activities are examined. We find that depending on their distinct network characteristics and location, unique and complex strategies are to be mastered for every cluster. Despite the many activities underway, none of them seems to have a strategic network to co-create a tailored defossilization strategy for the cluster - which is the core recommendation of this paper to develop.
In light of Egypt's transition to a green economy, this report focuses on reducing greenhouse gas (GHG) emissions and increasing resource efficiency along three different value chains in which small and medium-sized enterprises (SMEs) play a crucial role. In order to support SMEs in Egypt to take advantage of implementing greening options along value chains, more detailed analyses are needed. Therefore, the aim of this study is to analyse three selected supply chains to identify greening opportunities for SMEs. Against this background, the project report is structured as follows: Chapter 2 introduces the background with an overview over the concept of green economy followed by Egypt's economy and its green economy. This is followed by a presentation of the value chains and an overview of the respective sectors. Chapter 3 describes the research approach, methods and data collection. The following chapters examine the three selected value chains cotton, sugar beet and refrigerators, including environmental hot spots, greening options as well as the experts' evaluation of those greening options. The report concludes with key recommendations in Chapter 7.
Für Deutschland und viele Industrieländer weltweit wird der Import von grünem Wasserstoff ein zentraler Baustein auf dem Weg zur Klimaneutralität sein. Dabei muss einerseits gewährleistet sein, dass grüner Wasserstoff auch wirklich "grün" im Sinne von klimaneutral ist. Zugleich gibt es immer mehr Forderungen, dass auch andere Nachhaltigkeitskriterien - soziale, ökonomische und ökologische - bei der Produktion und dem Transport von Wasserstoff eingehalten werden. Der politisch getriebene Aufbau einer globalen Wasserstoffwirtschaft bietet von Anfang an die Möglichkeit, diesen Sektor in Einklang mit den bestehenden politischen Zielen zu bringen. Dazu zählen beispielsweise die Pariser Klimaziele oder die Agenda 2030. Die Industrienation Deutschland, die auch in Zukunft auf Energieimporte angewiesen sein wird, kann hier als führende Industrienation als Vorreiter Einfluss nehmen. Damit kann nicht nur sichergestellt werden, dass der nach Deutschland importierte Wasserstoff "grün und nachhaltig" ist, sondern auch die Nachhaltigkeit des globalen Wasserstoffmarktes insgesamt beeinflusst werden.
Diese Kurzstudie untersucht, welche bereits existierenden Politikinstrumente geeignet sind, Nachhaltigkeitskriterien für Wasserstoffimporte zu verankern und im Zusammenspiel den Weg zu einem nachhaltigen globalen Wasserstoffmarkt zu unterstützen. Dabei werden ausschließlich Nachhaltigkeitsziele und -kriterien jenseits der Klimawirkung von Wasserstoff analysiert. Es ist unbestritten, dass das zentrale Ziel der Wasserstoffwirtschaft die Reduktion von Treibhausgasen bis hin zur Klimaneutralität ist, was bereits in einer Vielzahl von Studien und Stellungnahmen diskutiert wurde. Daher wird in dieser Studie von der Klimaneutralität des grünen Wasserstoffs ausgegangen, um den Fokus auf die anderen wesentlichen Nachhaltigkeitsaspekte zu lenken, die für den Import von grünem und nachhaltigen Wasserstoff aus dem Globalen Süden von entscheidender Bedeutung sind.
Die Herstellung petrochemischer Grundstoffe ist sowohl energetisch als auch stofflich in Deutschland für rund 20 % der Nachfrage nach Mineralölprodukten verantwortlich. Das Gros fließt in die Produktion von Olefinen und Aromaten, welche als sogenannte Plattformchemikalien wiederum die Ausgangsbasis für die Herstellung von Polymeren und Kunststoffen darstellen. Letztgenannte sind von größter Relevanz für die Branche: Von den knapp 60 Milliarden Euro Umsatz, welche die deutsche petrochemische Industrie im Jahr 2021 generierte, entfiel gut die Hälfte auf das Marktsegment der Polymere. Daraus resultieren jedoch über die gesamte Wertschöpfungskette CO2-Emissionen von rund 50 Millionen Tonnen jährlich.
Eine Transformation der heutigen auf fossilen Rohstoffen basierenden petrochemischen Industrie hin zu einem auf erneuerbaren Rohstoffen basierenden zirkulären System kann somit einen bedeutenden Beitrag zu einer primärenergetisch effizienten und klimaneutralen Wirtschaftsweise leisten. Das vom Wuppertal Institut geleitete Forschungsprojekt GreenFeed exploriert gemeinsam mit den Verbundpartnern Karlsruher Institut für Technologie und Deutsches Biomasseforschungszentrum mögliche Pfade hin zu einem solchen System.
Vor diesem Hintergrund wird im vorliegenden Papier zunächst das heutige System der ökonomischen und stofflichen Synergiebeziehungen zwischen den Raffinerien und der chemischen Industrie analysiert. Im geografischen Fokus stehen dabei Deutschland und der ARRRA-Raum als bedeutendste Chemie-Region innerhalb Europas sowie inhaltlich der sehr relevante Teilbereich der Polymer-Produktion. Die Kerninhalte des Papiers sind:
1) Charakterisierung des petrochemischen Metabolismus in Deutschland, einschließlich Produktions-, Energie-, Feedstock- und Kohlenstoffbilanz sowie Infrastruktur- und Transport-Verflechtungen innerhalb dieses Systems und
2) regionale Vertiefungen in Form von insgesamt acht Steckbriefen über alle petrochemischen Kunststoff-Regionen in Deutschland sowie des Antwerpener und Rotterdamer Clusters.
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.
Do ngân sách các-bon còn lại trên toàn thế giới đang giảm nhanh chóng, các quốc gia trên toàn cầu đang tìm kiếm các giải pháp để hạn chế phát thải khí nhà kính. Ngành công nghiệp sản xuất và sử dụng than là một trong những ngành phát thải nhiều các-bon nhất, do vậy, các khu vực khai thác than sẽ bị ảnh hưởng đặc biệt bởi quá trình chuyển đổi sang hệ thống năng lượng và kinh tế trung hòa với khí hậu. Tại các khu vực thực hiện chuyển đổi, những thách thức không chỉ tồn tại trong lĩnh vực sản xuất năng lượng, bảo vệ môi trường, mà còn ở các lĩnh vực kinh tế và xã hội - thường được biết đến với khái niệm "Chuyển đổi Công bằng". Các cấp ra quyết định ở các khu vực khai thác than rất cần có các công cụ hỗ trợ giúp họ xác định các giải pháp chuyển đổi, vừa giúp đa dạng hóa nền kinh tế, vừa hỗ trợ người lao động và cộng đồng địa phương. Viện Wuppertal mong muốn hỗ trợ nâng cao năng lực cho các khu vực khai thác than trên toàn thế giới thông qua Bộ công cụ Chuyển dịch Công bằng – một tài liệu tổng quát, minh họa những thách thức và cơ hội của quá trình chuyển đổi bền vững. Bộ Công cụ này bao gồm kiến thức về xây dựng chiến lược, đưa ra các khuyến nghị về quản trị quá trình chuyển đổi, thúc đẩy việc làm bền vững, nêu bật các lựa chọn công nghệ và đề cập tới vấn đề phục hồi môi trường, tái sử dụng các cơ sở hạ tầng sản xuất than. Bộ Công cụ này được xây dựng dựa trên các nghiên cứu của Viện Wuppertal trong khuôn khổ “Sáng kiến của Liên Minh Châu Âu về chuyển dịch tại các khu vực khai thác than” và các kinh nghiệm thực tế của một số khu vực khai thác than trên toàn thế giới.
Wo werden zukünftig grüner Wasserstoff und synthetische Kraftstoffe produziert? Zu welchen Kosten können diese erzeugt werden? Und welchen Anteil hätte eine heimische Produktion daran? Die Ergebnisse der Studie MENA-Fuels zeigen, dass im Nahen Osten und Nordafrika langfristig sehr große kostengünstige Potenziale für grünen Strom, Wasserstoff und Synfuels bestehen. Die Berücksichtigung von Investitionsrisiken hat jedoch einen signifikanten Einfluss auf deren Kosten und damit auf die Wahl der potenziellen Exportländer.
Nigeria is Africa's top cement producer and could be on course to be one of the top producers globally. The goal of this study is to identify and critically examine the pathways available to Nigeria to meet its decarbonisation goals in the cement sector. Based on a literature review, the study assesses demand drivers and decarbonisation potentials for the sector. It then presents two different quantitative pathways for growth in production of cement by 2050, and three different pathways for decarbonisation of the sector. Using published data and a scenario analysis tool, the study calculates how the sector's emissions might evolve under each of these pathways. The results indicate that, in the most ambitious scenario, emissions from the sector can plateau by the late 2030s, resulting in an overall increase of 21% by 2050 (compared to 2015 levels). Achieving this scenario is necessary in order to put the sector on a path to net zero emissions beyond 2050. The scenario is driven by reductions in both energy-related and process emissions, as well as a small share of carbon capture and storage and demand management. A moderately ambitious scenario that relies mostly on savings on energy-related emissions results in an 84% increase in emissions by 2050. Finally, the Business-as-Usual scenario results in an almost tripling of emissions by 2050. The results indicate a strong potential for policies to drive improvements in energy efficiency and clinker-to-cement ratio. Critical areas of uncertainty within the assumptions include the production rates (including the evolution of the export market) and the fuel mix.