Material Flow Analysis and Life Cycle Assessment of Polyethylene Terephthalate and Polyolefin Plastics Supply Chains in the United States

Chaudhari, Utkarsh S.; Johnson, Anne T.; Reck, Barbara K.; Handler, Robert M.; Thompson, Vicki S.; Hartley, Damon; Young, Wendy B.; Watkins, David; Shonnard, David R.

doi:10.1021/acssuschemeng.2c04004

Cited by 25 publications

(26 citation statements)

References 33 publications

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“…LCA also uses resource consumption data to calculate the environmental impacts during the different stages of the process. 18 The integration of multiple methodologies for the evaluation of CE�for instance, combining MFA with LCA�provides analysis capable of identifying trade-offs between circularity and environmental impacts, 13,14,19 as suggested by earlier studies evaluating the sustainability of CE strategies for plastic packaging. 16,20,21 Most studies have evaluated the impacts of CE strategies as alternate waste management practices rather than as production technologies to translate from linear to circular manufacturing.…”

Section: ■ Introductionmentioning

confidence: 99%

Circular Economy Sustainability Analysis Framework for Plastics: Application for Poly(ethylene Terephthalate) (PET)

Gracida-Alvarez

Benavides

et al. 2023

ACS Sustainable Chem. Eng.

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The establishment of the circular economy (CE) for plastics aims to reduce material losses and dependence on virgin materials; however, this practice does not necessarily imply reduction of life-cycle impacts. In this study, a CE sustainability analysis framework combining life-cycle assessment (LCA) and material flow analysis (MFA) was developed to simultaneously evaluate the life-cycle impacts and circularity metrics of implementing different CE strategies of production of plastic packaging, using poly(ethylene terephthalate) (PET) bottles as an example. The strategies included increasing the recycling rate of PET bottles and integrating two chemical recycling technologies in industrial development: enzymatic hydrolysis and methanolysis. The energy use of enzymatic hydrolysis and methanolysis was estimated to be 57 and 38 MJ/kg PET, respectively, while the two technologies accounted for greenhouse gas (GHG) emissions of 3.0 and 2.0 kg CO2 e/kg PET, respectively. The analysis at the system level demonstrated that compared to the current practice, relying on 97% virgin PET resin, the joint implementation of these strategies generated similar GHG emissions (3.2 kg CO2 e/kg bottle) but reduced virgin material use and solid waste generation by 56 and 64%, respectively. Based on present technology development, increasing the share of mechanically recycled resin in bottle manufacturing and using a decarbonized electricity grid resulted in 14 and 9% lower GHG emissions, respectively, than the current supply chain.

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Section: ■ Introductionmentioning

confidence: 99%

Circular Economy Sustainability Analysis Framework for Plastics: Application for Poly(ethylene Terephthalate) (PET)

Gracida-Alvarez

Benavides

et al. 2023

ACS Sustainable Chem. Eng.

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“…Strikingly, the United States is the world's largest producer of plastic waste and also tops the world in annual per‐capita plastic waste generation in 2016 (Law et al., 2020). Studies have investigated the material flows of all plastics (Di et al., 2021; Heller et al., 2020; Law et al., 2020), or a single polymer (polyethylene terephthalate or PET) (Chaudhari et al., 2022; Smith et al., 2022), in the United States for a snapshot of 1 year. Long‐term, longitudinal dynamic material flow analysis of plastics is only available for PET in the United States (Kuczenski & Geyer, 2010).…”

Section: Introductionmentioning

confidence: 99%

Seven decades of plastic flows and stocks in the United States and pathways toward zero plastic pollution by 2050

Kan,

Wang,

Zhu

et al. 2023

J of Industrial Ecology

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The United States is the world's second‐largest producer and consumer of plastics and the largest producer of plastic waste. Understanding the sources, drivers, and destinations of plastic production, consumption, and waste is critical for the United States to develop strategies toward a zero‐plastic pollution future. Here, we characterize the dynamic material flows and stocks of plastics in the United States for nearly seven decades (1950–2018) and project the future trajectories until 2050 under various scenarios on the basis of reduce, reuse, and recycle to explore pathways toward zero plastic pollution. Our estimation shows that 1479 MMt plastics were produced in the United States from 1950 to 2018, 75 MMt waste plastics were domestically recycled, 139 MMt virgin polymers were exported, and 9 MMt recycled waste plastics were imported. Currently, about 326 MMt of plastics still remain in the society as in‐use stock, most of which (63%) are in the construction sector. Plastic pollution would almost double from 37 MMt in 2018 to 86 MMt in 2050 if current consumption pattern and waste management remain unchanged. Single strategies (i.e., plastic bag ban and extended lifespan) could only contribute limited reductions (2%–12%) of plastics pollution, and would not be able to reverse the increasing trajectory of plastic pollution until 2050. Additional measures are needed, such as improving recycling and avoiding landfilling of plastic waste. Our analysis can provide critical insights to help the United States develop long‐term strategies to mitigate and eliminate plastic pollution.

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“…Globally, 18 or 24% of nonfiber plastic waste is recycled or incinerated, respectively, and less than 10% is recycled in the United States . Although preferable to accumulation/landfilling, recycling is typically carried out by a mechanical or melt-and-remold process, yielding a product with inferior thermal, optical, and mechanical resilience. , Plastic incineration recovers only a fraction of the energy used in the production of the material as heat and may coproduce toxic combustion byproducts and greenhouse CO 2 , making it unacceptable as a “green” process. , …”

Section: Introductionmentioning

confidence: 99%

Rapid Polyolefin Plastic Hydrogenolysis Mediated by Single-Site Heterogeneous Electrophilic/Cationic Organo-group IV Catalysts

Edenfield,

Mason,

Lai

et al. 2023

ACS Catal.

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A homologous series of cationic electrophilic group IV metal hydrides (M = Ti, Zr, Hf) created by chemisorption of the corresponding MNp 4 precursors on highly Brønsted acidic sulfated alumina (AlS) to yield loosely coordinated surface AlS/MNp 2 (Np = neopentyl) species are systematically characterized by ICP, EXAFS/ XANES, DRIFTS, and solid-state high-resolution multidimensional NMR spectroscopy (SSNMR), as well as by energy span DFT computation. With effective stirring, these complexes readily undergo reaction with H 2 to yield AlS/M(alkyl)H species, which are highly active for the hydrogenolysis of diverse commercial polyethylenes, α-olefinethylene copolymers, isotactic polypropylene, and postconsumer polyolefins including high-density polyethylenes, yielding medium and small linear and branched hydrocarbons at turnover frequencies as high as 36,300 h −1 at 200 °C/17 atm H 2 for M = Zr. For given polyolefin and reaction conditions, turnover frequencies scale approximately as M = Zr > Hf > Ti, whereas catalyst thermal stability scales approximately as M = Hf ≈ Zr > Ti, and these trends are qualitatively understandable from the DFT analysis. These catalytic results reveal that the AlS/Hf(R)H-mediated hydrogenolysis favors wax-like and liquid products, whereas the AlS/Zr(R)H-mediated hydrogenolysis can be tuned between gases and liquids. DFT analysis identifies β-alkyl elimination as the turnover-limiting C−C scission process, which is particularly facile in these cationic d 0 complexes but not so in the neutrally charged analogues.

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Material Flow Analysis and Life Cycle Assessment of Polyethylene Terephthalate and Polyolefin Plastics Supply Chains in the United States

Cited by 25 publications

References 33 publications

Circular Economy Sustainability Analysis Framework for Plastics: Application for Poly(ethylene Terephthalate) (PET)

Circular Economy Sustainability Analysis Framework for Plastics: Application for Poly(ethylene Terephthalate) (PET)

Seven decades of plastic flows and stocks in the United States and pathways toward zero plastic pollution by 2050

Rapid Polyolefin Plastic Hydrogenolysis Mediated by Single-Site Heterogeneous Electrophilic/Cationic Organo-group IV Catalysts

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