Advances and Challenges in Low-Temperature Upcycling of Waste Polyolefins via Tandem Catalysis

Wei Zhang; Sungmin Kim; Michele L. Sarazen; Mingyuan He; Jingguang G. Chen; Johannes A. Lercher

doi:10.1002/anie.202500559

Advances and Challenges in Low-Temperature Upcycling of Waste Polyolefins via Tandem Catalysis

Wei Zhang^*
, Sungmin Kim
, Michele L. Sarazen
, Mingyuan He
, Jingguang G. Chen
, Johannes A. Lercher^*

^*此作品的通讯作者

化学与分子工程学院

Institute of Eco-Chongming
Pacific Northwest National Laboratory
Princeton University
Columbia University
Technical University of Munich

科研成果: 期刊稿件 › 文献综述 › 同行评审

15 引用（Scopus）

摘要

Polyolefin waste is the largest polymer waste stream that could potentially serve as an advantageous hydrocarbon feedstock. Upcycling polyolefins poses significant challenges due to their inherent kinetic and thermodynamic stability. Traditional methods, such as thermal and catalytic cracking, are straightforward but require temperatures exceeding 400 °C for complete conversion because of thermodynamic constraints. We summarize and critically compare recent advances in upgrading spent polyolefins and model reactants via kinetic (and thermodynamic) coupling of the endothermic C─C bond cleavage of polyolefins with exothermic reactions including hydrogenation, hydrogenolysis, metathesis, cyclization, oxidation, and alkylation. These approaches enable complete conversion to desired products at low temperatures (<300 °C). The goal is to identify challenges and possible pathways for catalytic conversions that minimize energy and carbon footprints.

源语言	英语
文章编号	e202500559
期刊	Angewandte Chemie - International Edition
卷	64
期	22
DOI	https://doi.org/10.1002/anie.202500559
出版状态	已出版 - 26 5月 2025

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abstract = "Polyolefin waste is the largest polymer waste stream that could potentially serve as an advantageous hydrocarbon feedstock. Upcycling polyolefins poses significant challenges due to their inherent kinetic and thermodynamic stability. Traditional methods, such as thermal and catalytic cracking, are straightforward but require temperatures exceeding 400 °C for complete conversion because of thermodynamic constraints. We summarize and critically compare recent advances in upgrading spent polyolefins and model reactants via kinetic (and thermodynamic) coupling of the endothermic C─C bond cleavage of polyolefins with exothermic reactions including hydrogenation, hydrogenolysis, metathesis, cyclization, oxidation, and alkylation. These approaches enable complete conversion to desired products at low temperatures (<300 °C). The goal is to identify challenges and possible pathways for catalytic conversions that minimize energy and carbon footprints.",

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AU - Zhang, Wei

AU - Kim, Sungmin

AU - Sarazen, Michele L.

AU - He, Mingyuan

AU - Chen, Jingguang G.

AU - Lercher, Johannes A.

PY - 2025/5/26

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N2 - Polyolefin waste is the largest polymer waste stream that could potentially serve as an advantageous hydrocarbon feedstock. Upcycling polyolefins poses significant challenges due to their inherent kinetic and thermodynamic stability. Traditional methods, such as thermal and catalytic cracking, are straightforward but require temperatures exceeding 400 °C for complete conversion because of thermodynamic constraints. We summarize and critically compare recent advances in upgrading spent polyolefins and model reactants via kinetic (and thermodynamic) coupling of the endothermic C─C bond cleavage of polyolefins with exothermic reactions including hydrogenation, hydrogenolysis, metathesis, cyclization, oxidation, and alkylation. These approaches enable complete conversion to desired products at low temperatures (<300 °C). The goal is to identify challenges and possible pathways for catalytic conversions that minimize energy and carbon footprints.

AB - Polyolefin waste is the largest polymer waste stream that could potentially serve as an advantageous hydrocarbon feedstock. Upcycling polyolefins poses significant challenges due to their inherent kinetic and thermodynamic stability. Traditional methods, such as thermal and catalytic cracking, are straightforward but require temperatures exceeding 400 °C for complete conversion because of thermodynamic constraints. We summarize and critically compare recent advances in upgrading spent polyolefins and model reactants via kinetic (and thermodynamic) coupling of the endothermic C─C bond cleavage of polyolefins with exothermic reactions including hydrogenation, hydrogenolysis, metathesis, cyclization, oxidation, and alkylation. These approaches enable complete conversion to desired products at low temperatures (<300 °C). The goal is to identify challenges and possible pathways for catalytic conversions that minimize energy and carbon footprints.

KW - C─C cleavage

KW - Exothermic reaction

KW - Mild conditions

KW - Polyolefin upcycling

KW - Tandem catalysis

UR - https://www.scopus.com/pages/publications/105000531271

U2 - 10.1002/anie.202500559

DO - 10.1002/anie.202500559

M3 - 文献综述

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JO - Angewandte Chemie - International Edition

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ER -

Advances and Challenges in Low-Temperature Upcycling of Waste Polyolefins via Tandem Catalysis

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