Showing 61–80 of 460

  • global non fossil c fuel demand in the transport sector – basic graphic (png) (copy)

    Global Non-fossil C-fuel Demand in the Transport Sector – Basic – Graphic (PNG)

    Markets & Economy, Policy, Sustainability & Health

    1 Page
    24 Downloads

    2025-01

    FREE

     
  • global non fossil c fuel demand in the transport sector – basic graphic (png) (copy)

    Global Non-fossil C-fuel Demand in the Transport Sector – Strong Ammonia – Graphic (PNG)

    Markets & Economy, Policy, Sustainability & Health

    1 Page
    15 Downloads

    2025-01

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  • global non fossil c fuel demand in the transport sector – strong ammonia graphic (png) (copy)

    Global Non-fossil C-fuel Demand in the Transport Sector – Strong CCU – Graphic (PNG)

    Markets & Economy, Policy, Sustainability & Health

    1 Page
    652 Downloads

    2025-01

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  • Add to
    cart    22 11 28 rc publications cover proceedings arc

    Advanced Recycling Conference 2024 (Proceedings)

    Markets & Economy, Policy, Sustainability & Health, Technology

    2024-12

    150  ex. tax

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    The proceedings of the Advanced Recycling Conference 2024 (20-21 November, https://advanced-recycling.eu) contain 42 conference presentations, the conference journal, sponsor documents and the press release.

  • rci position paper on chemical and physical recycling (pdf) (copy)

    Evaluation of Recent Reports on the Future of a Net-Zero Chemical Industry in 2050 (PDF)

    Markets & Economy, Policy, Sustainability & Health

    20 Pages
    1792 Downloads

    2024-11

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    The Renewable Carbon Initiative’s Scientific Background Report assesses 24 scenarios from 15 studies to envision a net-zero chemical industry by 2050. The analysis anticipates continued growth in chemical production, projecting a 2.4-fold increase in global feedstock demand by 2050 compared to 2020 levels, with most expansion expected outside Europe while European feedstock volumes remain stable. To achieve net-zero emissions, the industry is projected to undergo a significant shift in feedstocks, with key renewable carbon sources identified as biomass (22%), carbon capture and utilisation (33%), and recycling (20%), while the remaining 24% comes from fossil sources with carbon capture and storage. For plastics specifically, recycling is expected to play an even larger role, accounting for 42% of feedstocks on average. This transition will require continued innovation and investment in renewable carbon technologies to meet ambitious defossilisation goals.

    The report provides invaluable insights for industry leaders, policymakers, and researchers, highlighting the urgent need for action to achieve a net-zero future in the chemical sector by 2050.

    DOI No.: https://doi.org/10.52548/SXWV6083

  • – graphic (png)

    Net-Zero Plastics – Evaluation of Feedstock (%) Across 10 Scenarios from 7 Reports 2050 – Graphic (PNG)

    Markets & Economy, Policy, Sustainability & Health

    1 Page
    114 Downloads

    2024-11

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    The graph illustrates feedstock projections specifically for the plastics sector by 2050, analysing 10 scenarios from 7 reports, where recycling emerges as the dominant feedstock at 42% (combining mechanical and chemical recycling), while biomass (21%), CCU (17%), and fossil with CCS (19%) play supporting roles. The data shows less variation in projections compared to the chemical industry overall, suggesting stronger agreement on the future role of recycling in plastics production.

  • net zero plastics – evaluation of feedstock (%) across 10 scenarios from 7 reports 2050 – graphic (png) (copy)

    Net-Zero Chemical Industry – Evaluation of Feedstock (%) Across 16 Scenarios from 9 Reports 2050 – Graphic (PNG)

    Markets & Economy, Policy, Sustainability & Health

    1 Page
    95 Downloads

    2024-11

    FREE

     

    The graph shows the distribution of feedstock sources for the net-zero chemical industry by 2050, based on 16 scenarios from 9 reports, with CCU having the highest mean share at 33%, followed by biomass (22%), recycling (20%, split between mechanical and chemical), and fossil with CCS (24%). The data reveals significant variability across scenarios, particularly for CCU which ranges from near 0% to 90%, while both biomass and recycling show more moderate ranges, indicating a general consensus on their roles in the future chemical industry.

  • net zero chemical industry – evaluation of feedstock (%) across 16 scenarios from 9 reports 2050 – graphic (png) (copy)

    Net-Zero Plastics – Mean Feedstock Shares (%) Across 10 Scenarios From 7 Reports – Graphic (PNG)

    Markets & Economy, Policy, Sustainability & Health

    1 Page
    81 Downloads

    2024-11

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    The graph presents the mean feedstock shares for the 2050 net-zero plastics sector, derived from 10 scenarios across 7 reports. In this projection, recycling dominates with a 42% share, followed by biomass (21%), fossil & CCS (19%), and CCU (17%), highlighting the increased potential for circularity in the plastics industry compared to the broader chemical sector.

  • net zero plastics – mean feedstock shares (%) across 10 scenarios from 7 reports.png – graphic (png) (copy)

    Net-Zero Chemical Industry – Mean Feedstock Shares (%) Across 16 Scenarios From 9 Reports – Graphic (PNG)

    Markets & Economy, Policy, Sustainability & Health

    1 Page
    61 Downloads

    2024-11

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    The graph illustrates the mean feedstock shares projected for the 2050 net-zero chemical industry, based on 16 scenarios across 9 reports. The chart shows a diverse mix of feedstocks, with CCU (33%) and recycling (20%) playing significant roles alongside biomass (22%), while fossil & CCS still account for 24% of the feedstock share.

  • alternatives naphtha – den kreislauf für kunststoffe und reifen schließen: pyrolyseöl als chemischer rohstoff (gastbeitrag teil 3) (pdf)

    Alternatives Naphtha – Den Kreislauf für Kunststoffe und Reifen schließen: Pyrolyseöl als chemischer Rohstoff (Gastbeitrag Teil 3) (PDF)

    Markets & Economy, Technology

    1 Page
    95 Downloads

    2024-11

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    In den beiden vorangegangenen Artikeln dieser Serie wurde das Konzept des alternativen Naphthas als Ersatz für fossile Rohstoffe in Raffinerien und Steamcrackern vorgestellt. In diesem dritten Artikel konzentriert sich die Diskussion auf Pyrolyseöl, das durch chemisches Recycling von Kunststoffabfällen und Reifen gewonnen wird, und warum dies ein wichtiges „alternatives Naphtha“ für Raffinerien und Steamcracker ist.

    Relevante Anteile erneuerbarer Chemikalien und Polymere sind ohne „alternatives Naphtha“ nicht möglich. Ohne eine Abkehr von fossilem Naphtha wird es keine signifikante Defossilisierung des Chemiesektors geben.

    Dieser Artikel ist im Rahmen einer Serie von Gastbeiträgen im CHEManager erschienen. Es handelt sich um „Alternatives Naphtha Teil 3“ – aus CHEManager 11/2024.

    Hier finden sie den Artikel auch bei CHEManager.

     

  • die vielfalt des advanced recycling (2024)

    Die Vielfalt des Advanced Recycling (2024)

    Technology

    1 Page
    274 Downloads

    2024-11

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    Das gesamte Spektrum der verfügbaren Recyclingtechnologien, unterteilt nach ihren grundlegenden Funktionsprinzipien und ihren Produkten.

  • biodegradable polymers in various environments according to established standards and certification schemes – graphic (png, current version) (copy)

    Diversity of Advanced Recycling (2024)

    Technology

    1 Page
    707 Downloads

    2024-11

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    Full spectrum of available recycling technologies divided by their basic working principles and their products.

  • alternatives naphtha – herstellung und nutzung – wie erneuerbare rohstoffe zu naphtha verarbeitet werden (gastbeitrag teil 2) (pdf)

    Alternatives Naphtha – Herstellung und Nutzung – Wie erneuerbare Rohstoffe zu Naphtha verarbeitet werden (Gastbeitrag Teil 2) (PDF)

    Markets & Economy, Technology

    1 Page
    49 Downloads

    2024-10

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    Im ersten Artikel dieser dreiteiligen Serie wurde das Konzept „Alternatives Naphtha“ als Ersatz für fossile Rohstoffe in Raffinerien und Steamcrackern vorgestellt. Relevante Mengen erneuerbarer Chemikalien und Polymere sind ohne alternatives Naphtha nicht realisierbar, eine signifikante Defossilisierung des Chemiesektors erfordert den Verzicht auf fossiles Naphtha. Im zweiten Artikel wird die Herstellung und Nutzung von alternativem Naphtha genauer beleuchtet.

    Biobasierte Rohstoffe wie Fette, Öle und Schmierstoffe (Triglyceride) können fossile Erdölrohstoffe ersetzen und in bestehenden Raffinerien mitverarbeitet werden. Dies ist attraktiv, da Raffinerien ohne große Investitionen Biokraftstoffe und biobasierte Grundchemikalien produzieren können. Eine Vorbehandlung der Rohstoffe kann dabei erforderlich sein.

    Dieser Artikel ist im Rahmen einer Serie von Gastbeiträgen im CHEManager erschienen. Es handelt sich um „Alternatives Naphtha Teil 2“ – aus CHEManager 10/2024.

    Hier finden sie den Artikel auch bei CHEManager.

  • innovative bio based products for a clean transition (pdf)

    Forest-Based Biorefineries: Innovative Bio-Based Products for a clean Transition (PDF)

    Markets & Economy, Policy, Technology

    8 Pages
    385 Downloads

    2024-10

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    A new study conducted by the nova-Institute and commissioned by the Confederation of European Paper Industries (Cepi) unveils a significant surge in the European biorefinery sector, with forest-based biorefineries more than doubling their turnover to €6 billion since 2020. This remarkable growth underscores the rising demand for sustainable, bio-based alternatives to fossil-based products.

    The research, focused on the pulp and paper industry that produce additional bio-based products which land on the market beyond pulp and paper, identifies a total of 143 biorefineries across Europe, with 126 currently operational and 17 in development. The largest number of biorefineries is in Sweden, Finland, Germany, Portugal and Austria. The study points to a bright future for biorefineries, with projected annual growth rates of up to 5% until 2050.
    The products of these biorefineries provide sustainable solutions across various industries, from aviation to fashion, offering alternatives in materials, chemicals, fuels, food, and pharmaceuticals. Importantly, biorefineries contribute to Europe’s climate targets, with bio-based products already substituting over 3.1 megatons of CO2 emissions that would have been produced by fossil-based industries.

    The study emphasises that these advancements are not replacing traditional pulp and paper-making activities but are creating new revenue streams and increasing resource efficiency, providing a pathway to sustainable economic growth.

    Source: https://www.cepi.org/report-pulp-and-paper-biorefineries-in-europe-innovative-bio-based-products-for-a-clean-transition

  • die zukunft des recycling gestalten (pdf)

    Die Zukunft des Recyclings gestalten (PDF)

    Markets & Economy, Policy, Sustainability & Health, Technology

    2 Pages
    569 Downloads

    2024-10

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    Die ambitionierten Recyclingziele der EU, die (Selbst-)Verpflichtungen der chemischen Industrie und der Markenhersteller sowie die Anforderungen der Kunden üben einen enormen Entwicklungsdruck auf den Recyclingsektor aus. Einem großen Anteil nicht recycelter Abfallströme stehen die Nachfrage und die Suche nach erneuerbaren Rohstoffen für Chemikalien und Materialien gegenüber. Dies wirft die Frage auf, welche Technologien für welchen Abfallstrom am besten geeignet sind und wie die Umweltauswirkungen zu bewerten sind.

    Quelle: Advanced Recycling: Technologien und Markttrends für eine nachhaltige Kreislaufwirtschaft“ – aus CITplus 10/2024

  • nova paper #17: science based definition of natural polymers (pdf)

    nova-paper #17: Science-based Definition of Natural Polymers (PDF)

    Markets & Economy, Policy, Sustainability & Health

    22 Pages
    749 Downloads

    2024-09

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    European policy has defined „natural polymers“ in a way that has caused much concern and debate among scientists and industry, and has created a barrier to innovation. The authors of this report have carried out a comprehensive scientific evaluation of how the scientific literature defines „natural polymers“, and the result is: The European policy definition is partly in clear contrast to the scientific definitions.

    „Occurring in nature“ is the basis for every definition of „natural polymers“ in the scientific literature and in policy. All scientific definitions include biotechnological processes for the production of natural polymers. Not a single definition mentions the place of polymerisation as a criterion – in clear contrast to European policy. Industrial practice confirms this finding: A long list of widely accepted natural polymers includes biotechnologically processed polymers and the place of polymerisation is not a criterion.

    Conclusion: A policy definition of „natural polymers“ that is at odds with almost all scientific definitions and at odds with business reality, and which is a major barrier to innovation, green investment and lower carbon footprints, needs to be revised.
    The essence of the scientific definitions evaluated in this report is simple and leads to the following proposed definition: „Natural polymers are those that occur in nature, are produced in and extracted from nature, or can be produced identically using biotechnological processes“.

    DOI No.: https://doi.org/10.52548/UGBZ5516

  • european bioeconomy in figures 2014–2021 (pdf)

    European Bioeconomy in Figures 2014–2021 (PDF)

    Markets & Economy, Policy, Sustainability & Health

    29 Pages
    821 Downloads

    2024-09

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    The bioeconomy in the European Union is a strong contributor to the overall economy and accounts for over 16 million employees and more than 2.3 trillion Euro in turnover across all 27 Member States. In terms of turnover almost half of the 2.3 trillion Euro can be attributed to the food and feed industries, which remain a large part of the EU bioeconomy. Adding to this are the agriculture and forestry sectors providing primary biomass to bioeconomic processes. However, the sectors processing these feedstocks and manufacturing intermediate and end-use products, collectively referred to as the bio-based industries, find themselves contributing on a stable level to the overall bioeconomy and account for almost a third of the overall turnover.

     

  • alternatives naphtha – Artikel 1 im CHEManager

    Alternatives Naphtha – Erneuerbare Kohlenstoffquellen sollen der Defossilisierung der Chemieindustrie einen Schub verleihen (Gastbeitrag Teil 1) (PDF)

    Markets & Economy, Technology

    1 Page
    45 Downloads

    2024-09

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    Für die Defossilisierung der chemischen Industrie ist es entscheidend, Alternativen zu fossilem Naphtha zu finden. Relevante Anteile erneuerbarer Chemikalien und Polymere sind ohne „alternatives Naphtha“ nicht möglich.

    Das Konzept „alternatives Naphtha“ nutzt die bestehende Raffinerie-, Steamcracker- und Chemieindustrieinfrastruktur, in der ein Teil der fossilen Rohstoffe – Rohöl oder fossiles Naphtha – durch erneuerbare Kohlenstoffalternativen ersetzt werden kann, die aus den drei Quellen Biomasse, CO2 und Recycling stammen.

    Dieser Artikel ist im Rahmen einer Serie von Gastbeiträgen im CHEManager erschienen. Es handelt sich um „Alternatives Naphtha Teil 1“ – aus CHEManager 09/2024.

    Hier finden sie den Artikel auch bei CHEManager.

     

  • swift implementation of eu biotech and biomanufacturing initiative is key to strengthen eu competitiveness and accelerate defossilisation (pdf)

    RCI’s position paper: “Swift implementation of EU biotech and biomanufacturing initiative is key to strengthen EU competitiveness and accelerate defossilisation (PDF)”

    Markets & Economy, Policy, Sustainability & Health

    3 Pages
    473 Downloads

    2024-09

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    The Renewable Carbon Initiative’s position paper emphasizes that the EU must swiftly implement its biotechnology and biomanufacturing initiative to accelerate the shift from fossil carbon to renewable sources and boost competitiveness. The Renewable Carbon Initiative (RCI) highlights three key actions:

    1.) Align with Circular Economy Policies: Ensure consistency across EU initiatives to promote renewable carbon from biomass, recycling, and CCU.

    2.) Boost Market Demand: Address the lack of demand for renewable feedstocks by implementing policies to make fossil alternatives less competitive.

    3.) Enable Fossil-to-Renewable Transition: Repurposing current fossil-based manufacturing to use renewable feedstocks. Clear sustainability criteria, access to various biomass sources, and broader definitions of biomanufacturing processes are essential to achieving this transition.

    These actions are vital for achieving net-zero goals and strengthening EU industry.

  • renewable carbon initiative (rci) webinar slides – july 2024 (pdf)

    Renewable Carbon Initiative (RCI) Webinar slides – July 2024 (PDF)

    Policy, Sustainability & Health, Technology

    60 Pages
    509 Downloads

    2024-07

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    This document contains a generic set of slides to introduce the concept of renewable carbon and the Renewable Carbon Initiative. The focus of this webinar is the work and impact of the RCI. Moreover, Arndt Scheidgen, Head of Product Stewardship at Henkel Consumer Brands joined the webinar to give insights as an industry leader.