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  • Add to
    cart    NewCO2-based Fuels and Chemicals Conference 2026 (Proceedings, PDF) [Digital]

    CO2-based Fuels and Chemicals Conference 2026 (Proceedings, PDF)

    Markets & Economy, Policy, Sustainability & Health, Technology

    2026-05

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    The proceedings of the CO2-based Fuels and Chemicals Conference 2026 (28-29 April 2026, https://co2-chemistry.eu) contain all released presentations (download of the program leaflet, PDF) and the press release of the three winners of the Innovation Award “Best CO2 Utilisation 2026″.

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    info    Newsupport for bio based feedstock in plastic packaging analysis under the packaging and packaging waste regulation (eu) 2025/40 (affiliate product)

    Support for bio-based feedstock in plastic packaging analysis under the Packaging and Packaging Waste Regulation (EU) 2025/40 (Affiliate product)

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    Markets & Economy, Policy, Sustainability & Health, Technology

    100 Pages

    2026-05

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    New publication from nova experts for the European Commission

    This report assesses the role of bio-based feedstocks in plastic packaging under the EU’s Packaging and Packaging Waste Regulation (PPWR), with a focus on technological development and environmental performance. Although seventeen bio-based polymers are commercially available, they represent only ~1% of the global plastics market and account for just 4–5% of biogenic carbon in the EU chemical sector. Production capacity is concentrated in Asia (55%), followed by North America (17%) and the EU27+3 (14%). Despite their limited market share, there are no fundamental technical barriers to using them in packaging. Bio-based plastics offer a 30–70% reduction in greenhouse gas emissions compared to fossil-based alternatives, which supports the EU’s decarbonisation and circular economy goals. The report also evaluates the feasibility of setting targets for the use of bio-based materials, their equivalence with recycled materials and how sustainability criteria can be aligned with the Renewable Energy Directive (RED). Key recommendations include setting binding targets for bio-based content, establishing harmonised sustainability criteria, and adapting recycling infrastructure. Leveraging the complementarity of bio -based and recycled content could help to accelerate the EU’s transition to a climate-neutral packaging sector.
     
  • Add to
    cart    Newai circular economy conference 2026 (proceedings, pdf)

    AI Circular Economy Conference 2026 (Proceedings, PDF)

    Markets & Economy, Policy, Sustainability & Health, Technology

    2026-03

    150  ex. tax

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    The proceedings of the AI Circular Economy Conference 2026 (4-5 March, https://ai-circulareconomy.eu ) contain 25 conference presentations and the press release. Download of the program leaflet.

  • carbon dioxide utilisation and renewable energy − graphic (png)

    Carbon Dioxide Utilisation and Renewable Energy − Graphic (PNG)

    Markets & Economy, Technology

    1 Page
    55 Downloads

    2026-02

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  • bio based building blocks and polymers – global capacities, production and trends 2025–2030 (pdf)

    Bio-based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030 (PDF)

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    Markets & Economy

    23 Pages
    875 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

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    Plastics Production From 1950 to 2024 (PNG)

    Markets & Economy

    1 Page
    51 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • plastics production from 1950 to 2024 (png) (copy)

    Bio-based Polymer Capacities and Production Worldwide 2025 (PNG)

    Markets & Economy

    1 Page
    39 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • bio based polymers & plastics production 2024 worldwide (png)

    Bio-based Polymers & Plastics Production 2024 Worldwide (PNG)

    Markets & Economy

    1 Page
    34 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • bio based polymers & plastics production 2024 worldwide (png) (copy)

    Biomass Utilisation Worldwide (PNG)

    Markets & Economy

    1 Page
    50 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

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    Polymers and Bio-Based Shares Worldwide (2020–2025) (PNG)

    Markets & Economy

    1 Page
    36 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

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

    Bio-based polymers – Evolution of worldwide production capacities from 2018 to 2030 (PNG)

    Markets & Economy

    1 Page
    41 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • bio based polymers – evolution of worldwide production capacities from 2018 to 2030 (png) (copy)

    Global Production Capacities of Bio-based Polymers per region 2025 (PNG)

    Markets & Economy

    1 Page
    26 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • shares of produced bio based polymers per market sections (png)

    Bio-based non biodegradable polymers Evolution of Capacities (PNG)

    Markets & Economy

    1 Page
    21 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • bio based non biodegradable polymers evolution of capacities (png) (copy)

    Bio-based biodegradable polymers-Evolution Capacities to 2030 (PNG)

    Markets & Economy

    1 Page
    31 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • policy barriers for renewable carbon uptake – rci report (pdf)

    Policy Barriers for Renewable Carbon Uptake – RCI Report (PDF)

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    Policy

    19 Pages
    267 Downloads

    2026-02

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    Based on internal assessment of RCI member companies and joint analysis, this report reveals existing EU legislation which creates several roadblocks for the shift from fossil to renewable carbon, The report identifies ten concrete policy barriers across seven EU frameworks, including the ETS, REDIII, PPWR and SUPD.

    Key findings show regulatory misalignment (creating non-level playing fields and regulatory uncertainty), outdated definitions and misleading classifications (excluding innovative, climate-friendly products from incentives and market access) and impractical administrative bureaucracy (often conflicting with industrial realities). The biggest barrier is not identified in a single regulation, but identified as the lack of coherent support for renewable carbon in the chemicals and derived materials economy.

    The report provides practical suggestions to amend and fine-tune regulations in upcoming legislative revisions. It complements RCI’s policy proposal study published in 2025.

  • bio based biodegradable polymers evolution capacities to 2030 (png) (copy)

    Bio-based building blocks – Evolution of capacities to 2030 (PNG)

    Markets & Economy

    1 Page
    21 Downloads

    2026-02

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    The new high-level report “Bio‑based Building Blocks and Polymers – Global Capacities, Production and Trends 2025–2030”, compiled by the international biopolymer expert group of the nova-Institute, provides an overview of the capacities and production data of 17 commercially available bio‑based building blocks and polymers in 2025, along with a forecast for 2030. Detailed market data is available via individual workshops and webinars with the biopolymer experts. This data includes capacity development from 2018 to 2030, production data for the years 2024 and 2025, and analyses of market developments per building block, polymer and producers, as well as a statistical analysis of “Mass Balance and Attribution (MBA)” products available worldwide.

    2025 was a solid year for bio-based polymers, with an expected overall CAGR of 11 % to 2030 and an average capacity utilisation rate of 86 %. Overall, bio-based non-biodegradable polymers have larger installed capacities and higher utilisation rates than bio-based biodegradable polymers. While 58 % of the total installed capacities are from bio-based non-biodegradable polymers, 42 % are bio-based biodegradable polymers. Bio-based non-biodegradable have an average utilisation rate of 90 % whereas bio-based biodegradable polymers have an average utilisation rate of 81 %. The expected CAGR for both, bio-based non-biodegradable and biodegradable is similar with 10 % and 11 %, respectively.

    Epoxy resin and PUR production is growing moderately at 9 and 8 %, respectively, while PE and PP are increasing by 17 % and 94 %. Also, capacities for the biodegradables PHA and PLA are expected to increase until 2030 by 49 % and 16 %, respectively. Commercial newcomers such as casein polymers and PEF have increased production capacity and are expected to continue to grow significantly until 2030.

    DOI No.: https://doi.org/10.52548/PILO4285

  • when will ccu go mainstream? (pdf)

    When will CCU go mainstream? (PDF)

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    Markets & Economy

    4 Pages
    155 Downloads

    2026-01

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    As soon as renewable energy becomes cheap and abundant, which is closer than we think.

    The potential for carbon capture and utilisation (CCU) is tremendous. Utilising CO2 from fossil and biogenic sources, and eventually from the air (direct air capture), could easily meet the entire demand for embedded carbon of the global chemical and plastics industry. There are many different chemical and biotech pathways; most rely on CO2 plus hydrogen (H2) to produce intermediates such as CO, syngas, methane, methanol, formic acid, and naphtha.

    Almost all chemicals and plastics can be produced in this manner. According to experts at nova-Institute, an area the size of Greece (135,000 km2, equivalent to 1.5 % of the Sahara Desert or 0.8 % of all subtropical deserts combined) would be enough to produce sufficient green hydrogen via photovoltaics to meet the global chemical and plastics industry’s demand for embedded carbon with CCU by 2050. This calculation assumes that the demand for embedded carbon in chemicals and plastics will double from 550 million tonnes to 1,150 million tonnes (of carbon) by 2050. This simple calculation demonstrates the tremendous potential of CCU.

  • biorefineries in asia and the eu an exploratorive study (pdf)

    Biorefineries in Asia and the EU – an Explorative Study (PDF)

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    Markets & Economy, Policy, Technology

    58 Pages
    132 Downloads

    2026-01

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    The study aims to provide decision makers with a quick overview over the state of the bioeconomy in Europe and three selected countries in Asia, India, Thailand and Indonesia. Specific attention is placed on biorefineries, as they represent a key building block for the industry. Covered aspects include the political framework, technical pathways and existing infrastructure, alongside case studies. The study provides on-the ground insights from practioners in the field, includes a set of good-practice criteria to assess the prospects of biorefineries and offers a number of specific recommendations for future actions to expand the bioeconomy across continents.

  • recycling becomes feedstock for europe – let’s dare more autonomy (pdf)

    Recycling Becomes Feedstock for Europe – Let’s Dare More Autonomy (PDF)

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    Policy

    65 Pages
    500 Downloads

    2026-01

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    The paper shows how this goal of transformation or defossilisation can be implemented step by step and how legal areas can be better integrated at EU level, which will result in new priorities for both sectors. For example, in waste management, much of what does not contribute to the carbon supply of the chemical industry can be phased out gradually. It also includes enabling all recycling technologies, from mechanical and physical to chemical processes and even incineration with CO₂ capture and utilisation, since all processes are needed in the transformation for the different waste fractions and target products. Overall, the ten proposals derived and analysed in the paper also lead to a significant reduction in bureaucracy.

    There are some important proposals that build on instruments already introduced by the EU, such as substitution quotas for selected plastics sectors. The authors also specify proposals that are under discussion or being raised by Member States. However, there are also proposals to phase out existing regulations. It is important that the proposals build on each other and are implemented in a coordinated manner as part of a self-contained, phased overall package.

    Fortunately, greater autonomy is becoming mainstream in the EU and is also one of the cornerstones of the new EU Council Presidency. However, unless it becomes practical, greater autonomy and resilience will remain nothing more than a narrative. And the path to achieving this will be fraught with difficulties.

    DOI No.: https://doi.org/10.52548/LFPX3960

  • percentage change in the carbon footprint of plastics (png) (copy)

    RCI Webinar: Success Stories RCI 2025 and Outlook to 2026 – Project Results and Position Papers (PDF)

    Policy, Sustainability & Health

    59 Pages
    199 Downloads

    2025-12

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    The free RCI webinar on 9 December 2025 presented the RCI Success Stories 2025 and offered an Outlook to 2026. It showcased RCI’s policy impact at EU, national and international levels, highlighted key publications and scientific results (including the biomass study, Policy Proposals, LCA methodologies, sustainability criteria paper, and analysis of recent updates to methane and fossil CO2 emissions data in Life-Cycle Inventories (LCI)), and summarised member activities such as expert groups, roundtables, and survey insights. The webinar also introduced RCI’s ongoing and upcoming projects for 2026, including biodiversity, policy barriers, carbon flows, LCA case studies, and awareness-building initiatives.