Chain-Length-Controllable Upcycling of Polyolefins to Sulfate Detergents

Nuwayo Munyaneza, Ruiyang Ji, Adrian DiMarco, Joel Miscall, Lisa Stanley, Nicholas Rorrer, Rui Qiao, Guoliang Liu

Research output: Contribution to journalArticlepeer-review

1 Scopus Citations

Abstract

Escalating global plastic pollution and the depletion of fossil-based resources underscore the urgent need for innovative end-of-life plastic management strategies in the context of a circular economy. Thermolysis is capable of upcycling end-of-life plastics to intermediate molecules suitable for downstream conversion to eventually high-value chemicals, but tuning the molar mass distribution of the products is challenging. Here we report a temperature-gradient thermolysis strategy for the conversion of polyethylene and polypropylene into hydrocarbons with tunable molar mass distributions. The whole thermolysis process is catalyst- and hydrogen-free. The thermolysis of polyethylene and polyethylene/polypropylene mixtures with tailored temperature gradients generated oil with an average chain length of ~C14. The oil featured a high concentration of synthetically useful ..alpha..-olefins. Computational fluid dynamics simulations revealed that regulating the reactor wall temperature was the key to tuning the hydrocarbon distributions. Subsequent oxidation of the obtained ..alpha..-olefins by sulfuric acid and neutralization by potassium hydroxide afforded sulfate detergents with excellent foaming behaviour and emulsifying capacity and low critical micelle concentration. Overall, this work provides a viable approach to producing value-added chemicals from end-of-life plastics, improving the circularity of the anthropogenic carbon cycle.
Original languageAmerican English
JournalNature Sustainability
DOIs
StatePublished - 2024

NREL Publication Number

  • NREL/JA-2800-92165

Keywords

  • polymers
  • surfactant
  • upcycling

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