Hybrid substitution workflows should accelerate the uptake of chemical recyclates in polymer formulations

Attila Kovacs; Philippe Nimmegeers; Ana Cunha; Joost Brancart; Seyed Soheil Mansouri; Rafiqul Gani; Pieter Billen

doi:10.1016/j.cogsc.2023.100801

Hybrid substitution workflows should accelerate the uptake of chemical recyclates in polymer formulations

Attila Kovacs
, Philippe Nimmegeers
, Ana Cunha
, Joost Brancart
, Seyed Soheil Mansouri
, Rafiqul Gani
, Pieter Billen

Research output: Contribution to journal › Review article › peer-review

1 Scopus citations

Abstract

Chemical recycling of polymers is taking off as a circular technology, typically targeting pure recyclates. However, this is often not achieved efficiently due to high energy demand of separation and purification steps. In addition, many polymer applications have complex formulations that may be sensitive to impure feedstocks. Substitution of virgin feedstocks by complex recyclates (often containing impurities) requires a good knowledge of the structure/composition–property relations of polymer formulations. As this is often not the case, current practice relies on costly and rather inefficient enumeration experiments, or, at best, classical design-of-experiments approaches. We review the state-of-the art in structure–property modeling, present an example for polyurethane formulations, and propose a hybrid model-based framework. This involves a machine learning workflow for substitution problems in complex polymer formulations, combining existing data, novel reaction kinetics, structure–property models, molecular dynamics, and a minimum of experimental–analytical data where necessary, to build and validate the model.

Original language	English
Article number	100801
Journal	Current Opinion in Green and Sustainable Chemistry
Volume	41
DOIs	https://doi.org/10.1016/j.cogsc.2023.100801
State	Published - Jun 2023
Externally published	Yes

Funding

The authors gratefully acknowledge the Fonds voor Wetenschappelijk Onderzoek (FWO) Flanders for the financial support for the senior postdoctoral fellowships of Philippe Nimmegeers (1215523N) and Joost Brancart (12E1123N). Attila Kovács was supported by the University of Antwerp BOF DOCPRO3 40005. The authors gratefully acknowledge the Fonds voor Wetenschappelijk Onderzoek (FWO) Flanders for the financial support for the senior postdoctoral fellowships of Philippe Nimmegeers (1215523N) and Joost Brancart (12E1123N). Attila Kovács was supported by the U niversity of Antwerp BOF DOCPRO3 40005 .

Keywords

Experimental design
Machine learning
Molecular dynamics
Polymer formulation

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10.1016/j.cogsc.2023.100801

Cite this

@article{323997c23e874758aa98f7d2fd462658,

title = "Hybrid substitution workflows should accelerate the uptake of chemical recyclates in polymer formulations",

abstract = "Chemical recycling of polymers is taking off as a circular technology, typically targeting pure recyclates. However, this is often not achieved efficiently due to high energy demand of separation and purification steps. In addition, many polymer applications have complex formulations that may be sensitive to impure feedstocks. Substitution of virgin feedstocks by complex recyclates (often containing impurities) requires a good knowledge of the structure/composition–property relations of polymer formulations. As this is often not the case, current practice relies on costly and rather inefficient enumeration experiments, or, at best, classical design-of-experiments approaches. We review the state-of-the art in structure–property modeling, present an example for polyurethane formulations, and propose a hybrid model-based framework. This involves a machine learning workflow for substitution problems in complex polymer formulations, combining existing data, novel reaction kinetics, structure–property models, molecular dynamics, and a minimum of experimental–analytical data where necessary, to build and validate the model.",

keywords = "Experimental design, Machine learning, Molecular dynamics, Polymer formulation",

author = "Attila Kovacs and Philippe Nimmegeers and Ana Cunha and Joost Brancart and Mansouri, \{Seyed Soheil\} and Rafiqul Gani and Pieter Billen",

note = "Publisher Copyright: {\textcopyright} 2023 Elsevier B.V.",

year = "2023",

month = jun,

doi = "10.1016/j.cogsc.2023.100801",

language = "English",

volume = "41",

journal = "Current Opinion in Green and Sustainable Chemistry",

issn = "2452-2236",

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TY - JOUR

T1 - Hybrid substitution workflows should accelerate the uptake of chemical recyclates in polymer formulations

AU - Kovacs, Attila

AU - Nimmegeers, Philippe

AU - Cunha, Ana

AU - Brancart, Joost

AU - Mansouri, Seyed Soheil

AU - Gani, Rafiqul

AU - Billen, Pieter

PY - 2023/6

Y1 - 2023/6

N2 - Chemical recycling of polymers is taking off as a circular technology, typically targeting pure recyclates. However, this is often not achieved efficiently due to high energy demand of separation and purification steps. In addition, many polymer applications have complex formulations that may be sensitive to impure feedstocks. Substitution of virgin feedstocks by complex recyclates (often containing impurities) requires a good knowledge of the structure/composition–property relations of polymer formulations. As this is often not the case, current practice relies on costly and rather inefficient enumeration experiments, or, at best, classical design-of-experiments approaches. We review the state-of-the art in structure–property modeling, present an example for polyurethane formulations, and propose a hybrid model-based framework. This involves a machine learning workflow for substitution problems in complex polymer formulations, combining existing data, novel reaction kinetics, structure–property models, molecular dynamics, and a minimum of experimental–analytical data where necessary, to build and validate the model.

AB - Chemical recycling of polymers is taking off as a circular technology, typically targeting pure recyclates. However, this is often not achieved efficiently due to high energy demand of separation and purification steps. In addition, many polymer applications have complex formulations that may be sensitive to impure feedstocks. Substitution of virgin feedstocks by complex recyclates (often containing impurities) requires a good knowledge of the structure/composition–property relations of polymer formulations. As this is often not the case, current practice relies on costly and rather inefficient enumeration experiments, or, at best, classical design-of-experiments approaches. We review the state-of-the art in structure–property modeling, present an example for polyurethane formulations, and propose a hybrid model-based framework. This involves a machine learning workflow for substitution problems in complex polymer formulations, combining existing data, novel reaction kinetics, structure–property models, molecular dynamics, and a minimum of experimental–analytical data where necessary, to build and validate the model.

KW - Experimental design

KW - Machine learning

KW - Molecular dynamics

KW - Polymer formulation

UR - https://www.scopus.com/pages/publications/85151262477

U2 - 10.1016/j.cogsc.2023.100801

DO - 10.1016/j.cogsc.2023.100801

M3 - Review article

AN - SCOPUS:85151262477

SN - 2452-2236

VL - 41

JO - Current Opinion in Green and Sustainable Chemistry

JF - Current Opinion in Green and Sustainable Chemistry

M1 - 100801

ER -

Hybrid substitution workflows should accelerate the uptake of chemical recyclates in polymer formulations

Abstract

Funding

Keywords

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