Synergistic technologies for a circular economy: upcycling waste plastics and biomass

Ahmed I. Osman; Mahmoud Nasr; Chukwunonso O. Aniagor; Mohamed Farghali; Mee Mee Huang; Bridgid Lai Fui Chin; Ziqiang Sun; Serene Sow Mun Lock; Eduardo A. López-Maldonado; Chung Loong Yiin; Charles E. Chinyelu; Abid Salam Farooqi; Zhonghao Chen; Pow Seng Yap

doi:10.1007/s11705-024-2507-0

Synergistic technologies for a circular economy: upcycling waste plastics and biomass

Ahmed I. Osman^*, Mahmoud Nasr, Chukwunonso O. Aniagor, Mohamed Farghali, Mee Mee Huang, Bridgid Lai Fui Chin, Ziqiang Sun, Serene Sow Mun Lock, Eduardo A. López-Maldonado, Chung Loong Yiin, Charles E. Chinyelu, Abid Salam Farooqi, Zhonghao Chen, Pow Seng Yap^*

^*Corresponding author for this work

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

Abstract

The urgent need for sustainable waste management has led to the exploration of upcycling waste plastics and biomass as viable solutions. In 2018, global plastic production reached 359 million tonnes, with an estimated 12000 million tonnes projected to be delivered and disposed of in landfills by 2050. Unfortunately, current waste management practices result in only 19.5% of plastics being recycled, while the rest is either landfilled (55%) or incinerated (25.5%). The improper disposal of plastics contributes to issues such as soil and groundwater contamination, air pollution, and wildlife disturbance. On the other hand, biomass has the potential to deliver around 240 exajoules of energy per year by 2060. However, its current utilization remains relatively small, with only approximately 9% of biomass-derived energy being consumed in Europe in 2017. This review explores various upcycling methods for waste plastics and biomass, including mechanical, chemical, biological, and thermal approaches. It also highlights the applications of upcycled plastics and biomass in sectors such as construction, packaging, energy generation, and chemicals. The environmental and economic benefits of upcycling are emphasized, including the reduction of plastic pollution, preservation of natural resources, carbon footprint reduction, and circular economy advancement. (Figure presented.)

Original language	English
Article number	2
Journal	Frontiers of Chemical Science and Engineering
Volume	19
Issue number	1
DOIs	https://doi.org/10.1007/s11705-024-2507-0
Publication status	Published - Jan 2025

Keywords

biomass
circular economy
economic benefits
plastic waste
upcycling
waste management

UN SDGs

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

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10.1007/s11705-024-2507-0

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Osman, A. I., Nasr, M., Aniagor, C. O., Farghali, M., Huang, M. M., Chin, B. L. F., Sun, Z., Lock, S. S. M., López-Maldonado, E. A., Yiin, C. L., Chinyelu, C. E., Farooqi, A. S., Chen, Z., & Yap, P. S. (2025). Synergistic technologies for a circular economy: upcycling waste plastics and biomass. Frontiers of Chemical Science and Engineering, 19(1), Article 2. https://doi.org/10.1007/s11705-024-2507-0

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title = "Synergistic technologies for a circular economy: upcycling waste plastics and biomass",

abstract = "The urgent need for sustainable waste management has led to the exploration of upcycling waste plastics and biomass as viable solutions. In 2018, global plastic production reached 359 million tonnes, with an estimated 12000 million tonnes projected to be delivered and disposed of in landfills by 2050. Unfortunately, current waste management practices result in only 19.5% of plastics being recycled, while the rest is either landfilled (55%) or incinerated (25.5%). The improper disposal of plastics contributes to issues such as soil and groundwater contamination, air pollution, and wildlife disturbance. On the other hand, biomass has the potential to deliver around 240 exajoules of energy per year by 2060. However, its current utilization remains relatively small, with only approximately 9% of biomass-derived energy being consumed in Europe in 2017. This review explores various upcycling methods for waste plastics and biomass, including mechanical, chemical, biological, and thermal approaches. It also highlights the applications of upcycled plastics and biomass in sectors such as construction, packaging, energy generation, and chemicals. The environmental and economic benefits of upcycling are emphasized, including the reduction of plastic pollution, preservation of natural resources, carbon footprint reduction, and circular economy advancement. (Figure presented.)",

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AU - Osman, Ahmed I.

AU - Nasr, Mahmoud

AU - Aniagor, Chukwunonso O.

AU - Farghali, Mohamed

AU - Huang, Mee Mee

AU - Chin, Bridgid Lai Fui

AU - Sun, Ziqiang

AU - Lock, Serene Sow Mun

AU - López-Maldonado, Eduardo A.

AU - Yiin, Chung Loong

AU - Chinyelu, Charles E.

AU - Farooqi, Abid Salam

AU - Chen, Zhonghao

AU - Yap, Pow Seng

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N2 - The urgent need for sustainable waste management has led to the exploration of upcycling waste plastics and biomass as viable solutions. In 2018, global plastic production reached 359 million tonnes, with an estimated 12000 million tonnes projected to be delivered and disposed of in landfills by 2050. Unfortunately, current waste management practices result in only 19.5% of plastics being recycled, while the rest is either landfilled (55%) or incinerated (25.5%). The improper disposal of plastics contributes to issues such as soil and groundwater contamination, air pollution, and wildlife disturbance. On the other hand, biomass has the potential to deliver around 240 exajoules of energy per year by 2060. However, its current utilization remains relatively small, with only approximately 9% of biomass-derived energy being consumed in Europe in 2017. This review explores various upcycling methods for waste plastics and biomass, including mechanical, chemical, biological, and thermal approaches. It also highlights the applications of upcycled plastics and biomass in sectors such as construction, packaging, energy generation, and chemicals. The environmental and economic benefits of upcycling are emphasized, including the reduction of plastic pollution, preservation of natural resources, carbon footprint reduction, and circular economy advancement. (Figure presented.)

AB - The urgent need for sustainable waste management has led to the exploration of upcycling waste plastics and biomass as viable solutions. In 2018, global plastic production reached 359 million tonnes, with an estimated 12000 million tonnes projected to be delivered and disposed of in landfills by 2050. Unfortunately, current waste management practices result in only 19.5% of plastics being recycled, while the rest is either landfilled (55%) or incinerated (25.5%). The improper disposal of plastics contributes to issues such as soil and groundwater contamination, air pollution, and wildlife disturbance. On the other hand, biomass has the potential to deliver around 240 exajoules of energy per year by 2060. However, its current utilization remains relatively small, with only approximately 9% of biomass-derived energy being consumed in Europe in 2017. This review explores various upcycling methods for waste plastics and biomass, including mechanical, chemical, biological, and thermal approaches. It also highlights the applications of upcycled plastics and biomass in sectors such as construction, packaging, energy generation, and chemicals. The environmental and economic benefits of upcycling are emphasized, including the reduction of plastic pollution, preservation of natural resources, carbon footprint reduction, and circular economy advancement. (Figure presented.)

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KW - economic benefits

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Synergistic technologies for a circular economy: upcycling waste plastics and biomass

Abstract

Keywords

UN SDGs

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