2021
DOI: 10.1021/acssuschemeng.1c03786
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Hydrogenolysis of Polypropylene and Mixed Polyolefin Plastic Waste over Ru/C to Produce Liquid Alkanes

Abstract: Catalytic depolymerization of polyolefins is a promising chemical recycling strategy to create value-added products from waste plastics, which are accumulating in landfills and the natural environment at unsustainable rates. The cleavage of strong C−C bonds in polyolefins can be performed using a noble metal and hydrogen via a hydrogenolysis mechanism. Previously, we identified ruthenium nanoparticles supported on carbon (Ru/C) as a highly active heterogeneous catalyst for the conversion of polyethylene into l… Show more

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Cited by 162 publications
(146 citation statements)
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“…Thus, the reported reaction temperatures for Pt catalysts on polyolefin hydrogenolysis are relatively high (250−300°C) and the degradation time is fairly long 59,60 . As a cheaper active metal for hydrogenolysis, Ru‐based catalysts have drawn much attention in recent studies to catalyze polyolefins (including HDPE, LDPE, PP, waste polyolefins) to liquid fuels under mild conditions, with a reaction temperature of 200−250°C, H 2 pressure of 0−6 MPa, and reaction time from 0−12 h 56,61–64 . However, the following challenges still exist in this reaction: (1) high yield of low‐value gases (predominantly methane), generally above 10%, and (2) the long reaction time compared to the hydrocracking reaction.…”
Section: Chemical Upcycling Strategies Of Polyolefinsmentioning
confidence: 99%
“…Thus, the reported reaction temperatures for Pt catalysts on polyolefin hydrogenolysis are relatively high (250−300°C) and the degradation time is fairly long 59,60 . As a cheaper active metal for hydrogenolysis, Ru‐based catalysts have drawn much attention in recent studies to catalyze polyolefins (including HDPE, LDPE, PP, waste polyolefins) to liquid fuels under mild conditions, with a reaction temperature of 200−250°C, H 2 pressure of 0−6 MPa, and reaction time from 0−12 h 56,61–64 . However, the following challenges still exist in this reaction: (1) high yield of low‐value gases (predominantly methane), generally above 10%, and (2) the long reaction time compared to the hydrocracking reaction.…”
Section: Chemical Upcycling Strategies Of Polyolefinsmentioning
confidence: 99%
“…Ruthenium supported on metal oxides or carbon has been reported to catalyze the production of alkanes, aromatics, and liquid fuels from polyolefins (i.e., LDPE, HDPE, PP), PS, and PC. [881][882][883][884][885][886][887] LDPE, HDPE, and PP can be converted to liquid fuel (C5-C21) and lubricants/waxes (C22-C45) at low temperature and low H2 pressure (i.e., 200-250 °C, 20-30 bar) on metal oxides-supported Ru (e.g., Ru/TiO2, Ru/CeO2). [881][882] Over multifunctional Ru/Nb2O5, monocyclic aromatics can be selectively produced from single or mixed aromatic plastics (i.e., PET, PC, PS, polyphenylene oxide) at 200-320 °C in the presence of hydrogen and solvent (e.g., water, octane etc.).…”
Section: Hydrogenolysis With Noble Metalsmentioning
confidence: 99%
“…The support can be adjusted to treat different plastics and obtain varied products. [884][885][886][887] Over Ru/WO3/ ZrO2, LDPE can be converted into higher molecular weight fuels and wax/lubricant base-oils at 250 °C and 50 bar H2. 887 While on Ru/FAU, methane (>97%) can be produced from PE, PP, and PS under 50 bar H2 at 300-350 °C.…”
Section: Hydrogenolysis With Noble Metalsmentioning
confidence: 99%
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“…For example, thermochemical pathways used for plastic depolymerization, such as pyrolysis and thermal cracking, operate at temperatures >400 °C and suffer from low product selectivity [8] . Reductive catalytic depolymerization strategies, such as hydrogenolysis and metathesis, improve the energy efficiency by ameliorating reactions conditions (temperatures>200 °C), but require reductants such as high‐pressure H 2 and/or high‐cost noble metal catalysts [9,17–21] . Oxidative C−C bond cleavage generates oxygenated products as valuable chemicals, [3] but the traditional thermal catalysis approach requires bromine as a co‐catalyst, [22] impacting on the environment.…”
Section: Introductionmentioning
confidence: 99%