Bio-Polyethylene and Polyethylene Biocomposites: An Alternative toward a Sustainable Future

Xiang Yun Debbie Soo; Joseph Kinyanjui Muiruri; Wen Ya Wu; Jayven Chee Chuan Yeo; Suxi Wang; Nikodem Tomczak; Warintorn Thitsartarn; Beng Hoon Tan; Pei Wang; Fengxia Wei; Ady Suwardi; Jianwei Xu; Xian Jun Loh; Qingyu Yan; Qiang Zhu

doi:10.1002/marc.202400064

Bio-Polyethylene and Polyethylene Biocomposites: An Alternative toward a Sustainable Future

Xiang Yun Debbie Soo, Joseph Kinyanjui Muiruri, Wen Ya Wu, Jayven Chee Chuan Yeo, Suxi Wang, Nikodem Tomczak, Warintorn Thitsartarn, Beng Hoon Tan, Pei Wang, Fengxia Wei, Ady Suwardi, Jianwei Xu, Xian Jun Loh, Qingyu Yan^*, Qiang Zhu^*

^*Corresponding author for this work

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

18 Citations (Scopus)

Abstract

Polyethylene (PE), a highly prevalent non-biodegradable polymer in the field of plastics, presents a waste management issue. To alleviate this issue, bio-based PE (bio-PE), derived from renewable resources like corn and sugarcane, offers an environmentally friendly alternative. This review discusses various production methods of bio-PE, including fermentation, gasification, and catalytic conversion of biomass. Interestingly, the bio-PE production volumes and market are expanding due to the growing environmental concerns and regulatory pressures. Additionally, the production of PE and bio-PE biocomposites using agricultural waste as filler materials, highlights the growing demand for sustainable alternatives to conventional plastics. According to previous studies, addition of ≈50% defibrillated corn and abaca fibers into bio-PE matrix and a compatibilizer, results in the highest Young's modulus of 4.61 and 5.81 GPa, respectively. These biocomposites have potential applications in automotive, building construction, and furniture industries. Moreover, the advancement made in abiotic and biotic degradation of PE and PE biocomposites is elucidated to address their environmental impacts. Finally, the paper concludes with insights into the opportunities, challenges, and future perspectives in the sustainable production and utilization of PE and bio-PE biocomposites. In summary, production of PE and bio-PE biocomposites can contribute to a cleaner and sustainable future.

Original language	English
Article number	2400064
Journal	Macromolecular Rapid Communications
Volume	45
Issue number	14
DOIs	https://doi.org/10.1002/marc.202400064
Publication status	Published - Jul 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2024 Wiley-VCH GmbH.

ASJC Scopus Subject Areas

Polymers and Plastics
Organic Chemistry
Materials Chemistry

Keywords

agricultural waste
biocomposite
degradation
polyethylene
sustainability

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/marc.202400064

Cite this

Soo, X. Y. D., Muiruri, J. K., Wu, W. Y., Yeo, J. C. C., Wang, S., Tomczak, N., Thitsartarn, W., Tan, B. H., Wang, P., Wei, F., Suwardi, A., Xu, J., Loh, X. J., Yan, Q., & Zhu, Q. (2024). Bio-Polyethylene and Polyethylene Biocomposites: An Alternative toward a Sustainable Future. Macromolecular Rapid Communications, 45(14), Article 2400064. https://doi.org/10.1002/marc.202400064

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title = "Bio-Polyethylene and Polyethylene Biocomposites: An Alternative toward a Sustainable Future",

abstract = "Polyethylene (PE), a highly prevalent non-biodegradable polymer in the field of plastics, presents a waste management issue. To alleviate this issue, bio-based PE (bio-PE), derived from renewable resources like corn and sugarcane, offers an environmentally friendly alternative. This review discusses various production methods of bio-PE, including fermentation, gasification, and catalytic conversion of biomass. Interestingly, the bio-PE production volumes and market are expanding due to the growing environmental concerns and regulatory pressures. Additionally, the production of PE and bio-PE biocomposites using agricultural waste as filler materials, highlights the growing demand for sustainable alternatives to conventional plastics. According to previous studies, addition of ≈50% defibrillated corn and abaca fibers into bio-PE matrix and a compatibilizer, results in the highest Young's modulus of 4.61 and 5.81 GPa, respectively. These biocomposites have potential applications in automotive, building construction, and furniture industries. Moreover, the advancement made in abiotic and biotic degradation of PE and PE biocomposites is elucidated to address their environmental impacts. Finally, the paper concludes with insights into the opportunities, challenges, and future perspectives in the sustainable production and utilization of PE and bio-PE biocomposites. In summary, production of PE and bio-PE biocomposites can contribute to a cleaner and sustainable future.",

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author = "Soo, {Xiang Yun Debbie} and Muiruri, {Joseph Kinyanjui} and Wu, {Wen Ya} and Yeo, {Jayven Chee Chuan} and Suxi Wang and Nikodem Tomczak and Warintorn Thitsartarn and Tan, {Beng Hoon} and Pei Wang and Fengxia Wei and Ady Suwardi and Jianwei Xu and Loh, {Xian Jun} and Qingyu Yan and Qiang Zhu",

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doi = "10.1002/marc.202400064",

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T1 - Bio-Polyethylene and Polyethylene Biocomposites

T2 - An Alternative toward a Sustainable Future

AU - Soo, Xiang Yun Debbie

AU - Muiruri, Joseph Kinyanjui

AU - Wu, Wen Ya

AU - Yeo, Jayven Chee Chuan

AU - Wang, Suxi

AU - Tomczak, Nikodem

AU - Thitsartarn, Warintorn

AU - Tan, Beng Hoon

AU - Wang, Pei

AU - Wei, Fengxia

AU - Suwardi, Ady

AU - Xu, Jianwei

AU - Loh, Xian Jun

AU - Yan, Qingyu

AU - Zhu, Qiang

PY - 2024/7

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N2 - Polyethylene (PE), a highly prevalent non-biodegradable polymer in the field of plastics, presents a waste management issue. To alleviate this issue, bio-based PE (bio-PE), derived from renewable resources like corn and sugarcane, offers an environmentally friendly alternative. This review discusses various production methods of bio-PE, including fermentation, gasification, and catalytic conversion of biomass. Interestingly, the bio-PE production volumes and market are expanding due to the growing environmental concerns and regulatory pressures. Additionally, the production of PE and bio-PE biocomposites using agricultural waste as filler materials, highlights the growing demand for sustainable alternatives to conventional plastics. According to previous studies, addition of ≈50% defibrillated corn and abaca fibers into bio-PE matrix and a compatibilizer, results in the highest Young's modulus of 4.61 and 5.81 GPa, respectively. These biocomposites have potential applications in automotive, building construction, and furniture industries. Moreover, the advancement made in abiotic and biotic degradation of PE and PE biocomposites is elucidated to address their environmental impacts. Finally, the paper concludes with insights into the opportunities, challenges, and future perspectives in the sustainable production and utilization of PE and bio-PE biocomposites. In summary, production of PE and bio-PE biocomposites can contribute to a cleaner and sustainable future.

AB - Polyethylene (PE), a highly prevalent non-biodegradable polymer in the field of plastics, presents a waste management issue. To alleviate this issue, bio-based PE (bio-PE), derived from renewable resources like corn and sugarcane, offers an environmentally friendly alternative. This review discusses various production methods of bio-PE, including fermentation, gasification, and catalytic conversion of biomass. Interestingly, the bio-PE production volumes and market are expanding due to the growing environmental concerns and regulatory pressures. Additionally, the production of PE and bio-PE biocomposites using agricultural waste as filler materials, highlights the growing demand for sustainable alternatives to conventional plastics. According to previous studies, addition of ≈50% defibrillated corn and abaca fibers into bio-PE matrix and a compatibilizer, results in the highest Young's modulus of 4.61 and 5.81 GPa, respectively. These biocomposites have potential applications in automotive, building construction, and furniture industries. Moreover, the advancement made in abiotic and biotic degradation of PE and PE biocomposites is elucidated to address their environmental impacts. Finally, the paper concludes with insights into the opportunities, challenges, and future perspectives in the sustainable production and utilization of PE and bio-PE biocomposites. In summary, production of PE and bio-PE biocomposites can contribute to a cleaner and sustainable future.

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KW - biocomposite

KW - degradation

KW - polyethylene

KW - sustainability

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ER -

Bio-Polyethylene and Polyethylene Biocomposites: An Alternative toward a Sustainable Future

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

UN SDGs

Access to Document

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