Renewable Carbon Publications nova provides studies on
all renewable carbon relevant
topics such as

4 Covers bio-based & CO₂-based polymers
as well as chemical recycling
 Data for 2023:
24 06 10 slider publications bio based cover Report on Bio-based
Building Blocks and
Polymers
More details Advanced Recycling Figure 24 06 10 slider publications advanced recycling cover Report on
Advanced Plastic
Waste Recycling
Technologies

More details 22 07 06 pha cover More details Report on
The PHA Industry
Landscape Download PDF here Networking Opportunities
Recent Reports
Expert Information
nova-Institute Logo Networking and Knowledge Flyer 2024 Everything at a glance

Showing 1–20 of 588

2040All
  • Select
    licence    Newbio based building blocks and polymers – global capacities, production and trends 2024–2029 (pdf)

    Bio-based Building Blocks and Polymers – Global Capacities, Production and Trends 2024–2029 (PDF)

    New

    Markets & Economy

    434 Pages

    2025-03

    3,000 10,000  ex. tax

    Plus 19% MwSt.
    Press
    release     Select
    licence

    2024 was a respectable year for bio-based polymers, with an overall expected CAGR of 13 % to 2029. Overall, bio-based biodegradable polymers have large installed capacities with an expected CAGR of 17 % to 2029, but the current average capacity utilisation is moderate at 65 %. In contrast, bio-based non-biodegradable polymers have a much higher utilisation rate of 90 %, but will only grow by 10 % to 2029.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PP and cyclic APC capacities are increasing by 30 %. Despite a decline in production of biodegradables, especially for PLA in Asia, capacities have increased by 40 %. The same applies to PHA capacities. Commercial newcomers such as casein polymers and PEF recorded a rise in production capacity and are expected to continue to grow significantly until 2029.

    DOI No.: https://doi.org/10.52548/UMTR4695

  • New(pdf)

    Bio-based Building Blocks and Polymers Global Capacities, Production and Trends 2024–2029 – Short Version (PDF)

    New

    Markets & Economy

    28 Pages
    307 Downloads

    2025-03

    FREE

    Free Shipping
     

    2024 was a respectable year for bio-based polymers, with an overall expected CAGR of 13 % to 2029. Overall, bio-based biodegradable polymers have large installed capacities with an expected CAGR of 17 % to 2029, but the current average capacity utilisation is moderate at 65 %. In contrast, bio-based non-biodegradable polymers have a much higher utilisation rate of 90 %, but will only grow by 10 % to 2029.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PP and cyclic APC capacities are increasing by 30 %. Despite a decline in production of biodegradables, especially for PLA in Asia, capacities have increased by 40 %. The same applies to PHA capacities. Commercial newcomers such as casein polymers and PEF recorded a rise in production capacity and are expected to continue to grow significantly until 2029.

  • Newevaluating lca approaches and methodologies for renewable carbon sources report 3 of 3 – non technical summary (march 2025)

    Evaluating LCA Approaches and Methodologies for Renewable Carbon Sources Report 3 of 3 – Non-technical Summary (March 2025) (PDF)

    New

    Markets & Economy, Policy, Sustainability & Health

    15 Pages
    312 Downloads

    2025-03

    FREE

    Free Shipping
     

    This Non-technical Summary (15 pages),highlights main insights into the project results and states key take-aways for policy-makers.

    It compares several frameworks, such as ISO 14040, Product Environmental Footprint (PEF), and GHG Protocol, finding both commonalities and critical differences in areas like biogenic carbon accounting and recycling assessment. The study identifies significant methodological flexibility in existing frameworks, leading to inconsistencies in LCA results and challenges in standardisation. Key issues include differing treatment of carbon capture and utilisation (CCU), direct air capture (DAC), and allocation of environmental burdens in multifunctional processes. Policy recommendations emphasise the need for harmonisation, improved biogenic carbon accounting, and clear guidance on emerging technologies like DAC and mass balance attribution. Overall, the study calls for refining LCA methodologies to ensure fair comparison between renewable and fossil-based carbon solutions.

    This report is the third report of a larger RCI project on LCA methodology, which includes two additional publications:

    Report 1 of 3 – Renewable Carbon in LCA Guidelines
    Report 2 of 3 – Renewable Carbon in Recycling Situations

    Please find these additional reports by following the respective links at the bottom of this page.

  • Newevaluating lca approaches and methodologies for renewable carbon sources report 2 of 3 – renewable carbon in recycling situations (march 2025) (pdf)

    Evaluating LCA Approaches and Methodologies for Renewable Carbon Sources Report 2 of 3 – Renewable Carbon in Recycling Situations (March 2025) (PDF)

    New

    Markets & Economy, Policy, Sustainability & Health

    37 Pages
    212 Downloads

    2025-03

    FREE

    Free Shipping
     

    This report focuses on renewable carbon in recycling scenarios and the key challenges in LCA and carbon footprint assessments. It examines system boundaries, allocation methods, and biogenic carbon accounting approaches, highlighting their influence on sustainability evaluations. The report emphasises the cut-off and avoided-burden approaches for recycling while recommending the -1/+1 method for biogenic carbon transparency. However, it also identifies contradictions between LCA results and broader sustainability goals, such as the EU waste hierarchy, which prioritises recycling. To address these inconsistencies, the report suggests integrating LCA with additional sustainability metrics like land use and recyclability. Ultimately, refining these methodologies will enhance the accuracy and reliability of environmental assessments for bio-based and recycled materials.

    This report is the second report of a larger RCI project on LCA methodology, which includes two additional publications:

    Report 1 of 3 – Renewable Carbon in LCA Guidelines
    Report 3 of 3 – Non-technical Summary

    Please find these additional reports by following the respective links at the bottom of this page.

  • Newevaluating lca approaches and methodologies for renewable carbon sources report 1 of 3 – renewable carbon in lca guidelines (march 2025) (pdf)

    Evaluating LCA Approaches and Methodologies for Renewable Carbon Sources Report 1 of 3 – Renewable Carbon in LCA Guidelines (March 2025) (PDF)

    New

    Markets & Economy, Policy, Sustainability & Health

    145 Pages
    316 Downloads

    2025-03

    FREE

    Free Shipping
     

    Renewable Carbon in LCA Guidelines (146 pages) evaluates methodological choices which impact LCAs for products containing renewable carbon in existing LCA frameworks and guidelines. The study specifically examines the similarities and differences in the methodological choices of guidelines, as well as the implications of these methodological aspects on the resulting LCA outcomes.The frameworks were selected based on their relevance and legitimacy in the industry, academia and policy field, and include: ISO 14040/44, ISO 14067, GHG Protocol Product Standard, PACT’s Pathfinder Framework, the PCF Guideline for the chemical industry by Together for Sustainability (TfS), EPD for the construction industry – ISO 14025 and EN 15804, the Renewable Energy Directive, the Product Environmental Footprint (PEF) and the JRC’s plastics LCA methodology. One field with a particularly large methodological freedom is recycling.

    This report is the first report of a larger RCI project on LCA methodology, which includes two additional publications:

    Report 2 of 3 – Renewable Carbon in Recycling Situations
    Report 3 of 3 – Non-technical Summary

    Please find these additional reports by following the respective links at the bottom of this page.

  • sustainable textiles the way forward (pdf)

    Sustainable textiles – the way forward (PDF)

    New

    Markets & Economy, Sustainability & Health

    6 Pages
    212 Downloads

    2025-02

    FREE

    Free Shipping
     
    High reliance on fossil carbon, associated high carbon footprint, low recycling rates and microplastics:
    Several solutions are emerging. The article analyses the evolution of the textile industry from 1960 to today, fossil and bio-based as well as recycling.
    The future of sustainable textiles
    The sustainable textile industry of the future will be built on a foundation of cotton fibres and fast-growing cellulose fibres, later strongly supported by bio- and CO2-based synthetic fibres (“biosynthetics”) and high recycling rates for all types of fibres. This combination can eventually replace most fossil-based synthetic fibres by 2050.
  • bio based polymers worldwide (pdf)

    Bio-based Polymers Worldwide (PDF)

    New

    Markets & Economy, Policy, Sustainability & Health

    5 Pages
    339 Downloads

    2025-02

    FREE

    Free Shipping
     
    Expert insight into capacity developments, investments and new policy frameworks:
    • Firstly, global capacity for bio-based polymers will grow strongly over the next five years, much faster than for fossil-based polymers
    • Secondly, investments in new capacity will take place in China, Europe, the Middle East, and the US
    • Thirdly, investment in bio-based polymer capacities is mainly driven by policy frameworks that create demand.
  • is there enough biomass to defossilise the chemicals and derived materials sector by 2050? – a joint bic and rci scientific background report (pdf) (copy)

    Joint Webinar hosted by Bio-based Industries Consortium (BIC) and the Renewable Carbon Initiative (RCI) (February 2025) (PDF)

    New

    Policy, Sustainability & Health

    51 Pages
    153 Downloads

    2025-02

    FREE

    Free Shipping
     

    The webinar was presented by Michael Carus (nova-Institute, RCI), supported by Christopher vom Berg (RCI), Dirk Carrez (BIC), and Marco Rupp (BIC). It was based on a Scientific Background Report “Is there enough biomass to defossilise the chemicals and derived materials sector by 2050?” commissioned by the Bio-based Industries Consortium (BIC) and the Renewable Carbon Initiative (RCI).

    It explored whether agricultural and woody biomass could sustainably meet 20% of the carbon demand for the chemical and derived materials sectors by 2050. Using models like CAPRI (for agriculture) and TiMBA (for forestry), the study examined different scenarios, balancing food, feed, and biofuel priorities. Results showed that with moderate technological advancements, this 20% target is achievable without compromising sustainability or biodiversity. Stronger high-tech scenarios could even provide up to 40%, though existing biofuel policies may limit this. Overall, the study concluded that biomass could play a key role in defossilising the chemical sector, given the right innovations and policy frameworks.

     

  • evaluation of recent reports on the future of a net zero chemical industry in 2050 (pdf) (copy)

    Is there Enough Biomass to Defossilise the Chemicals and Derived Materials Sector by 2050? – A Joint BIC and RCI Scientific Background Report (PDF)

    New

    Markets & Economy, Policy, Sustainability & Health

    41 Pages
    905 Downloads

    2025-02

    FREE

    Free Shipping
     

    This reports presents the findings of a joint project of the Bio-based Industries Consortium (BIC) and the Renewable Carbon Initiative (RCI), which focuses on whether agricultural and woody biomass combined sustainably provide enough biomass to meet 20% of the future carbon demand of the chemical and derived materials industries in 2050 (up from 5.5% (EU27) and 10% (global) in 2023).

    This leading question was investigated with professional experts to model a business-as-usual, a low resource depletion, and a high-tech scenario to better analyse the possible ranges of biomass availability under different developments.

    Agriculture: By 2050, under the BAU scenario, production is projected to increase by 31% to 5.07 billion tonnes. Cereals increase by 32% to 3.1 billion tonnes, sugar by 40% to 340 million tonnes and vegetable oils by 45% to 317 million tonnes. In the Green LRD scenarios, production is projected to increase by 24–26%, and in the Green HT scenarios by 38–53% – compared to 31% in the BAU scenario.

    Forestry: Global supply and demand of industrial roundwood (coniferous and non-coniferous) will increase by an estimated 38% between 2020 and 2050, from 0.9 to 1.3 billion tdm. The largest increase in supply is expected in Asia (69%), including China and Russia, but a significant increase of 32% is also seen for Europe.

    The report concludes that sustainably meeting 20% of total carbon demand of the chemicals and derived materials sector in 2050 via biomass seems a realistic and achievable estimate.

    DOI No.: https://doi.org/10.52548/PIRL6916

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

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

    New

    Markets & Economy, Policy, Sustainability & Health

    22 Pages
    580 Downloads

    2024-09

    FREE

    Free Shipping
     

    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

  • Select
    licence    alternative naphtha – technologies and market, status and outlook (pdf)

    Alternative Naphtha – Technologies and Market, Status and Outlook (PDF)

    New

    Markets & Economy, Technology

    188 Pages

    2024-07

    2,500 9,000  ex. tax

    Plus 19% MwSt.
     
    Select
    licence

    For the defossilisation of the chemical industry, it is crucial to find alternatives to fossil-based naphtha. The “alternative naphtha” concept makes use of existing refinery, steam cracking and chemical industry infrastructure where a proportion of fossil-based feedstocks – crude oil or fossil-based naphthas can be replaced by renewable carbon alternatives derived from the three sources of renewable carbon: CO2, biomass and recycling.

    This new report by nova-Institute presents an analysis of the routes, associated technologies, market players and volumes by which renewable carbon can be introduced to refinery and steam cracking operations as replacement for fossil based feedstocks.

    With 188 pages, 22 tables and illustrated by 48 graphics the report provides a comprehensive view on the growth in capacity for these alternative sources of naphtha as chemical industry feedstock, production routes and the need for “upgrading”, key companies and partnerships and the regulatory environment.

    DOI No.: https://doi.org/10.52548/JICP8041

  • Add to
    cart    New

    Cellulose Fibres Conference 2025 (Proceedings, PDF)

    Markets & Economy, Policy, Sustainability & Health, Technology

    2025-03

    150  ex. tax

    Plus 19% MwSt.
    Press
    release     Add to
    cart

    The Cellulose Fibres Conference 2025 – New with Biosynthetics! (https://cellulose-fibres.eu, 12-13 March 2025, Cologne, hybrid) covered the entire value chain of the sustainable textile industry, from lignocellulose, pulp, cellulose fibres such as rayon, viscose, modal or lyocell and new developments to a wide range of applications:
    Textiles from renewable fibres, non-wovens such as wet wipes, as well as areas such as composites, hygiene, packaging or nano cellulose in the food industry. This year, for the first time, the conference included a dedicated session on biosynthetics – a promising area to complement the alternative for bio-based textiles. Deep insights have been offered into the future of cellulose fibres, which fits perfectly with the current shift towards circular economy, recycling and sustainable carbon cycles.

    The Cellulose Fibres Conference Proceedings include all released conference presentations, the conference journal, sponsor documents and the conference press release.

  • Newpolymers and bio based shares worldwide (2020–2025) (png) (copy)

    Schematic Differentiation of Pathways of Drop-in (PNG)

    Markets & Economy

    1 Page
    16 Downloads

    2025-03

    FREE

    Free Shipping
     
  • Newschematic differentiation of pathways of drop in (png) (copy)

    Shares of the Produced Bio-based Polymers in Different Market Segments in 2024 (PNG)

    Markets & Economy

    1 Page
    21 Downloads

    2025-03

    FREE

    Free Shipping
     
  • Newbio based polymer capacities and production worldwide 2024 (png) (copy)

    Bio-based Non Biodegradable Polymers Evolution of Worldwide Prod Capacities 2029 (PNG)

    Markets & Economy

    1 Page
    5 Downloads

    2025-03

    FREE

    Free Shipping
     
  • Newbio based biodegradable polymers evolution of worldwide production capacities 2029 (png)

    Bio-based Biodegradable Polymers Evolution of Worldwide Production Capacities 2029 (PNG)

    Markets & Economy

    1 Page
    8 Downloads

    2025-03

    FREE

    Free Shipping
     
  • Newbio based biodegradable polymers evolution of worldwide production capacities 2029 (png) (copy)

    Bio-based polymers – Evolution of worldwide production capacities from 2018 to 2029 (PNG)

    Markets & Economy

    1 Page
    15 Downloads

    2025-03

    FREE

    Free Shipping
     
  • Newbio based polymers – evolution of worldwide production capacities from 2018 to 2029 (png) (copy)

    Biomass Utilisation Worldwide 2024 (PNG)

    Markets & Economy

    1 Page
    22 Downloads

    2025-03

    FREE

    Free Shipping
     
  • Newbiomass utilisation worldwide 2024 (png) (copy)

    Global Production Capacities of Bio-based Polymers per region 2024 (PNG)

    Markets & Economy

    1 Page
    11 Downloads

    2025-03

    FREE

    Free Shipping
     
  • Newglobal production capacities of bio based polymers per region 2024 (png) (copy)

    Pathways to bio-based polymers (PNG)

    Markets & Economy

    1 Page
    21 Downloads

    2025-03

    FREE

    Free Shipping