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Closed-loop recycling of polyethylene-like materials

Author

Listed:
  • Manuel Häußler

    (University of Konstanz)

  • Marcel Eck

    (University of Konstanz)

  • Dario Rothauer

    (University of Konstanz)

  • Stefan Mecking

    (University of Konstanz)

Abstract

Plastics are key components of almost any technology today. Although their production consumes substantial feedstock resources, plastics are largely disposed of after their service life. In terms of a circular economy1–8, reuse of post-consumer sorted polymers (‘mechanical recycling’) is hampered by deterioration of materials performance9,10. Chemical recycling1,11 via depolymerization to monomer offers an alternative that retains high-performance properties. The linear hydrocarbon chains of polyethylene12 enable crystalline packing and provide excellent materials properties13. Their inert nature hinders chemical recycling, however, necessitating temperatures above 600 degrees Celsius and recovering ethylene with a yield of less than 10 per cent3,11,14. Here we show that renewable polycarbonates and polyesters with a low density of in-chain functional groups as break points in a polyethylene chain can be recycled chemically by solvolysis with a recovery rate of more than 96 per cent. At the same time, the break points do not disturb the crystalline polyethylene structure, and the desirable materials properties (like those of high-density polyethylene) are fully retained upon recycling. Processing can be performed by common injection moulding and the materials are well-suited for additive manufacturing, such as 3D printing. Selective removal from model polymer waste streams is possible. In our approach, the initial polymers result from polycondensation of long-chain building blocks, derived by state-of-the-art catalytic schemes from common plant oil feedstocks, or microalgae oils15. This allows closed-loop recycling of polyethylene-like materials.

Suggested Citation

  • Manuel Häußler & Marcel Eck & Dario Rothauer & Stefan Mecking, 2021. "Closed-loop recycling of polyethylene-like materials," Nature, Nature, vol. 590(7846), pages 423-427, February.
    • Handle: RePEc:nat:nature:v:590:y:2021:i:7846:d:10.1038_s41586-020-03149-9
    DOI: 10.1038/s41586-020-03149-9
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    Citations

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    Cited by:

    1. Sheng Wang & Nannan Wang & Dan Kai & Bofan Li & Jing Wu & Jayven Chee Chuan YEO & Xiwei Xu & Jin Zhu & Xian Jun Loh & Nikos Hadjichristidis & Zibiao Li, 2023. "In-situ forming dynamic covalently crosslinked nanofibers with one-pot closed-loop recyclability," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    2. Daniel H. Weinland & Kevin van der Maas & Yue Wang & Bruno Bottega Pergher & Robert-Jan van Putten & Bing Wang & Gert-Jan M. Gruter, 2022. "Overcoming the low reactivity of biobased, secondary diols in polyester synthesis," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    3. Xiaozhuang Zhou & Yijun Zheng & Haohui Zhang & Li Yang & Yubo Cui & Baiju P. Krishnan & Shihua Dong & Michael Aizenberg & Xinhong Xiong & Yuhang Hu & Joanna Aizenberg & Jiaxi Cui, 2023. "Reversibly growing crosslinked polymers with programmable sizes and properties," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    4. Xing-Wang Han & Xun Zhang & Youyun Zhou & Aizezi Maimaitiming & Xiu-Li Sun & Yanshan Gao & Peizhi Li & Boyu Zhu & Eugene Y.-X. Chen & Xiaokang Kuang & Yong Tang, 2024. "Circular olefin copolymers made de novo from ethylene and α-olefins," Nature Communications, Nature, vol. 15(1), pages 1-11, December.

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