Tandem Heterogeneous Catalysis for Polyethylene Depolymerization Via an Olefin-Intermediate Process

Overview

Journal ACS Sustain Chem Eng

Publisher American Chemical Society

Date 2024 May 6

PMID 38706722

Authors

Lucas D Ellis

Sara V Orski

Grace A Kenlaw

Andrew G Norman

Kathryn L Beers

Yuriy Roman-Leshkov

Gregg T Beckham

Affiliations

Soon will be listed here.

Abstract

The accumulation of plastic waste in the environment has prompted the development of new chemical recycling technologies. A recently reported approach employed homogeneous organometallic catalysts for tandem dehydrogenation and olefin cross metathesis to depolymerize polyethylene (PE) feedstocks to a mixture of alkane products. Here, we build on that prior work by developing a fully heterogeneous catalyst system using a physical mixture of SnPt/γ-AlO and ReO/γ-AlO. This heterogeneous catalyst system produces a distribution of linear alkane products from a model, linear C alkane, -eicosane, and from a linear PE substrate (which is representative of high-density polyethylene), both in an -pentane solvent. For the PE substrate, a molecular weight decrease of 73% was observed at 200 °C in 15 h. This type of tandem chemistry is an example of an olefin-intermediate process, in which poorly reactive aliphatic substrates are first activated through dehydrogenation and then functionalized or cleaved by a highly-active olefin catalyst. Olefin-intermediate processes like that examined here offer both a selective and versatile means to depolymerize polyolefins at lower severity than traditional pyrolysis or cracking conditions.

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