The Contribution of High-resolution GC Separations in Plastic Recycling Research

Overview

Journal Anal Bioanal Chem

Specialty Chemistry

Date 2023 Jan 17

PMID 36650250

Authors

Delphine Zanella

Monica Romagnoli

Sofia Malcangi

Marco Beccaria

Tatiana Chenet

Chiara De Luca

Fabio Testoni

Luisa Pasti

Ugo Visentini

Giampiero Morini

Alberto Cavazzini

Flavio A Franchina

Affiliations

Soon will be listed here.

Abstract

One convenient strategy to reduce environmental impact and pollution involves the reuse and revalorization of waste produced by modern society. Nowadays, global plastic production has reached 367 million tons per year and because of their durable nature, their recycling is fundamental for the achievement of the circular economy objective. In closing the loop of plastics, advanced recycling, i.e., the breakdown of plastics into their building blocks and their transformation into valuable secondary raw materials, is a promising management option for post-consumer plastic waste. The most valuable product from advanced recycling is a fluid hydrocarbon stream (or pyrolysis oil) which represents the feedstock for further refinement and processing into new plastics. In this context, gas chromatography is currently playing an important role since it is being used to study the pyrolysis oils, as well as any organic contaminants, and it can be considered a high-resolution separation technique, able to provide the molecular composition of such complex samples. This information significantly helps to tailor the pyrolysis process to produce high-quality feedstocks. In addition, the detection of contaminants (i.e., heteroatom-containing compounds) is crucial to avoid catalytic deterioration and to implement and design further purification processes. The current review highlights the importance of molecular characterization of waste stream products, and particularly the pyrolysis oils obtained from waste plastics. An overview of relevant applications published recently will be provided, and the potential of comprehensive two-dimensional gas chromatography, which represents the natural evolution of gas chromatography into a higher-resolution technique, will be underlined.

Citing Articles

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