Towards circular plastics within planetary boundaries

Bachmann, Marvin; Zibunas, Christian; Hartmann, Jan; Tulus, Víctor; Suh, Sangwon; Guillén‐Gosálbez, Gonzalo; Bardow, André

doi:10.1038/s41893-022-01054-9

Cited by 74 publications

(57 citation statements)

References 51 publications

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“…Although the commercial demand for plastics has doubled in the past 20 years, 1,2 the current plastics industry is far from being sustainable. 3−5 Of the 391 Mt of plastics produced worldwide in 2021, only 8.3% was derived from postconsumer recyclates.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Although the commercial demand for plastics has doubled in the past 20 years, , the current plastics industry is far from being sustainable. − Of the 391 Mt of plastics produced worldwide in 2021, only 8.3% was derived from postconsumer recyclates . There is hence an urgent need to develop a circular economy to curb the accumulation of plastic waste throughout the earth’s ecosystems. ,,, Among the established and emerging strategies for revalorizing plastic waste, ,− mechanical recycling is an appealing approach in terms of time, economic cost, and environmental impact. ,− Its main drawback is that it commonly yields materials with inferior mechanical properties compared to virgin materials, which is largely due to chain degradation during reprocessing and contamination by incompatible polymers. ,, Polyethylene (PE) and polypropylene (PP), which together constitute approximately half of the world’s polymer production, lose approximately 95% of their value at the end of their life with current recycling technology .…”

Section: Introductionmentioning

confidence: 99%

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Upcycling Polyolefin Blends into High-Performance Materials by Exploiting Azidotriazine Chemistry Using Reactive Extrusion

Vialon,

Sun,

Formon

et al. 2024

J. Am. Chem. Soc.

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The revalorization of incompatible polymer blends is a key obstacle in realizing a circular economy in the plastics industry. Polyolefin waste is particularly challenging because it is difficult to sort into its constituent components. Untreated blends of polyethylene and polypropylene typically exhibit poor mechanical properties that are suitable only for low-value applications. Herein, we disclose a simple azidotriazine-based grafting agent that enables polyolefin blends to be directly upcycled into high-performance materials by using reactive extrusion at industrially relevant processing temperatures. Based on a series of model experiments, the azidotriazine thermally decomposes to form a triplet nitrene species, which subsequently undergoes a complex mixture of grafting, oligomerization, and cross-linking reactions; strikingly, the oligomerization and cross-linking reactions proceed through the formation of nitrogen−nitrogen bonds. When applied to polyolefin blends during reactive extrusion, this combination of reactions leads to the generation of amorphous, phase-separated nanostructures that tend to exist at polymer−polymer interfaces. These nanostructures act as multivalent cross-linkers that reinforce the resulting material, leading to dramatically improved ductility compared with the untreated blends, along with high dimensional stability at high temperatures and excellent mechanical recyclability. We propose that this unique behavior is derived from the thermomechanically activated reversibility of the nitrogen− nitrogen bonds that make up the cross-linking structures. Finally, the scope of this chemistry is demonstrated by applying it to ternary polyolefin blends as well as postconsumer polyolefin feedstocks.

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Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Upcycling Polyolefin Blends into High-Performance Materials by Exploiting Azidotriazine Chemistry Using Reactive Extrusion

Vialon,

Sun,

Formon

et al. 2024

J. Am. Chem. Soc.

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“…Chemical recycling to monomer (CRM) is a powerful tool in efforts to circularize the plastic economy. , Indeed, recent systemic analyses of the high greenhouse gas emissions for future plastics systems all highlight the imperative for major increases in recycling to preserve both the waste plastic embedded energy and material value. − So far, chemical recycling to monomer is most often demonstrated using newly invented polymers, with great potential as future circular materials, but not currently found in existing waste streams. − It is equivalently important to develop chemical recycling to true monomer using currently used commercial plastics. Poly( l -lactic acid) (PLLA) is one of the largest commercial, sustainable polymers, produced at 200,000–300,000 tonne/annum, and sourced from crops, via fermentation of starches to l -lactic acid. , The lactic acid undergoes polycondensation to form oligoesters, which are thermally decomposed to form the cyclic dimer l -lactide ( l -LA) .…”

Section: Introductionmentioning

confidence: 99%

Chemical Recycling of Commercial Poly(l-lactic acid) to l-Lactide Using a High-Performance Sn(II)/Alcohol Catalyst System

McGuire,

Buchard,

Williams

2023

J. Am. Chem. Soc.

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Poly(L-lactic acid) (PLLA) is a leading commercial polymer produced from biomass, showing useful properties for plastics and fiber applications; after use, it is compostable. One area for improvement is postconsumer waste PLLA chemical recycling to monomer (CRM), i.e., the formation of L-lactide (L-LA) from waste plastic. This process is currently feasible at high reaction temperatures and shows low catalytic activity accompanied, in some cases, by side reactions, including epimerization. Here, a commercial Sn(II) catalyst, applied with nonvolatile commercial alcohol, enables highly efficient CRM of PLLA to yield L-LA in excellent yield and purity (92% yield, >99% L-LA from theoretical max.). The depolymerization is performed using neat polymer films at low temperatures (160 °C) under a nitrogen flow or vacuum. The chemical recycling operates with outstanding activity, achieving turnover frequencies which are up to 3000× higher than previously excellent catalysts and applied at loadings up to 6000× lower than previously leading catalysts. The catalyst system achieves a TOF = 3000 h −1 at 0.01 mol % or 1:10,000 catalyst:PLLA loading. The depolymerization of waste PLLA plastic packaging (coffee cup lids) produces pure L-LA in excellent yield and selectivity. The new catalyst system (Sn + alcohol) can itself be recycled four times in different PLLA "batch degradations" and maintains its high catalytic productivity, activity, and selectivity.

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“…The current trend tries to include the assessment of the absolute sustainability level of decarbonization pathways for the chemical industry, which has been appointed as a key strategy to guide development as well as policy-making . Several studies that apply the PB framework for decision-making have been published in recent years. − Galán-Martin et al applied PB-LCA to evaluate the transition of the petrochemical industry to renewable carbon-based, highlighting the opportunities to incorporate PBs in the decision-making when assessing large-scale decarbonization routes. D’Angelo et al assessed the absolute sustainability performance of low-carbon ammonia synthesis routes from the PB-LCA perspective.…”

Section: Introductionmentioning

confidence: 99%

The Relevance of Life Cycle Assessment Tools in the Development of Emerging Decarbonization Technologies

Fernández-González,

Rumayor,

Domínguez-Ramos

et al. 2023

JACS Au

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The development of emerging decarbonization technologies requires advanced tools for decision-making that incorporate the environmental perspective from the early design. Today, Life Cycle Assessment (LCA) is the preferred tool to promote sustainability in the technology development, identifying environmental challenges and opportunities and defining the final implementation pathways. So far, most environmental studies related to decarbonization emerging solutions are still limited to midpoint metrics, mainly the carbon footprint, with global sustainability implications being relatively unexplored. In this sense, the Planetary Boundaries (PBs) have been recently proposed to identify the distance to the ideal reference state. Hence, PB-LCA methodology can be currently applied to transform the resource use and emissions to changes in the values of PB control variables. This study shows a complete picture of the LCA’s role in developing emerging technologies. For this purpose, a case study based on the electrochemical conversion of CO2 to formic acid is used to show the possibilities of LCA approaches highlighting the potential pitfalls when going beyond greenhouse gas emission reduction and obtaining the absolute sustainability level in terms of four PBs.

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Towards circular plastics within planetary boundaries

Cited by 74 publications

References 51 publications

Upcycling Polyolefin Blends into High-Performance Materials by Exploiting Azidotriazine Chemistry Using Reactive Extrusion

Upcycling Polyolefin Blends into High-Performance Materials by Exploiting Azidotriazine Chemistry Using Reactive Extrusion

Chemical Recycling of Commercial Poly(l-lactic acid) to l-Lactide Using a High-Performance Sn(II)/Alcohol Catalyst System

The Relevance of Life Cycle Assessment Tools in the Development of Emerging Decarbonization Technologies

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