Selective Electrocatalytic Degradation of Ether‐Containing Polymers

Hsu, Jesse H.; Ball, Tyler E.; Oh, Sewon; Stache, Erin E.; Fors, Brett P.

doi:10.1002/anie.202316578

Angew Chem Int Ed

2023

DOI: 10.1002/anie.202316578

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Selective Electrocatalytic Degradation of Ether‐Containing Polymers

Jesse H. Hsu,

Tyler E. Ball,

Sewon Oh

et al.

Abstract: Leveraging electrochemistry to degrade robust polymeric materials has the potential to impact society's growing issue of plastic waste. Herein, we develop an electrocatalytic oxidative degradation of polyethers and poly(vinyl ethers) via electrochemically mediated hydrogen atom transfer (HAT) followed by oxidative polymer degradation promoted by molecular oxygen. We investigated the selectivity and efficiency of this method, finding our conditions to be highly selective for polymers with hydridic, electron‐ric… Show more

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2024

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Cited by 8 publications

References 87 publications

(148 reference statements)

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Polyester Upcycling to Glycine via Tandem Thermochemical–Electrochemical Catalysis

Ma,

Chen,

Yuan

et al. 2024

Advanced Energy Materials

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Deconstruction of polyethylene terephthalate (PET) plastics into commodity chemicals such as glycine presents a promising route for waste valorization. However, directly upcycling PET into glycine via thermocatalysis typically requires harsh conditions (e.g., high H2 pressure and elevated temperature) while suffering from limited selectivity and high carbon footprint. Herein, a cascade thermochemical–electrochemical catalysis is developed to exploit glycine from end‐of‐life PET plastics with high selectivity and yield, without the use of hydrogen gas in the entire process. PET is first degraded into oxalic acid via thermochemical oxidative depolymerization using an active and robust HY‐zeolite‐supported Au catalyst under a low O2 pressure (0.3 MPa), and then valorize oxalic acid intermediate into glycine via a two‐step electroreduction over an earth‐abundant TiO2 catalyst. The proposed cascade catalysis approach is resilient to impurities from realistic PET waste streams, and enables a continuous conversion of various PET goods into glycine with an overall yield of 75%. Techno‐economic analysis and life cycle assessment demonstrate that the cascade approach is a cost‐effective and low‐carbon route for PET upcycling. This hybrid thermochemical–electrochemical technology paves a way to leverage cascade catalysis for mitigating plastic pollution while producing high‐value chemicals.

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Polyester Upcycling to Glycine via Tandem Thermochemical–Electrochemical Catalysis

Ma,

Chen,

Yuan

et al. 2024

Advanced Energy Materials

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N‐Oxyl Radicals in Oxidative C−O Coupling: Free‐Radical Hydrogen Substitution and Addition to C=C Bonds

Lopat'eva,

Krylov,

et al. 2024

Asian J Org Chem

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N‐oxyl radicals occupy an important place in free‐radical oxidative CH‐functionalization being one of the most efficient redox‐organocatalysts for hydrogen atom abstraction (HAT). Their applications include aerobic radical chain autoxidation, CH‐functionalization with the formation of carbon‐carbon and carbon‐heteroatom bonds. The persistent nature of N‐oxyl radicals combined with their high reactivity in HAT results in their unique dual chemistry: the same radical can both propagate radical chain reaction (at low N‐oxyl concentrations) and effectively “terminate” carbon‐centered radicals (at higher N‐oxyl concentrations). The latter case opens a new synthetic application area of N‐oxyl radicals, in which they act as both hydrogen abstracting species and O‐reagents for cross‐coupling with carbon‐centered radicals thus produced. Apart from the C–H bond cleavage, reactive N‐oxyl radicals have been extensively used recently in C=C double bond functionalization via radical addition reactions. In this review, both free‐radical CH‐functionalization reactions with the introduction of N‐oxyl fragments and alkene difunctionalizations by N‐oxyls are covered with emphasis on the relationship between reaction conditions and selectivity.

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Anodisches Recycling von gängigen Polymeren: Die Kombination von Eisen‐Elektrokatalyse und skalierbarer Wasserstoffentwicklungsreaktion

Hourtoule,

Trienes,

Ackermann

2024

Angewandte Chemie

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Kunststoffe sind in unserem Alltag allgegenwärtig, und die Akkumulation von Kunststoffabfällen in unserer Umwelt stellt ein großes gesellschaftliches Problem dar. Daher sind Methoden für das Recycling von Kunststoffabfällen im Hinblick auf eine künftige Kreislaufwirtschaft von hohem Interesse. Insbesondere der Abbau von Polymeren nach Nutzung durch Verbraucher hin zu wertschöpfenden kleinen Molekülen stellt eine nachhaltige Strategie für eine Kohlenstoff‐Kreislaufwirtschaft dar. Trotz jüngster Fortschritte ist der chemische Polymerabbau nach wie vor weitgehend auf chemische Redox‐Reagenzien beschränkt oder durch eine geringe Energieeffizienz photochemischer Prozesse limitiert. In dieser Arbeit berichten wir über einen leistungsstarken eisenkatalysierten Abbau von Polystyrolen mit hohem Molekulargewicht durch Elektrochemie, um effizient monomere Benzoylprodukte zu liefern. Die Robustheit der Ferraelektrokatalyse wurde durch den Abbau von verschiedenen realen Nach‐Gebrauchs‐Kunststoffen, ebenfalls im Gramm‐Maßstab, bestätigt. Die kathodische Halbreaktion wurde weitgehend durch die Wasserstoffentwicklungsreaktion (HER) dargestellt. Der skalierbare elektrolytische Polymerabbau konnte ausschließlich mit Solarenergie über ein handelsübliches Solarpanel betrieben werden, was auf ein herausragendes Potenzial für eine dezentralisierte, grüne Wasserstoffwirtschaft hinweist.

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Selective Electrocatalytic Degradation of Ether‐Containing Polymers

Cited by 8 publications

References 87 publications

Polyester Upcycling to Glycine via Tandem Thermochemical–Electrochemical Catalysis

Polyester Upcycling to Glycine via Tandem Thermochemical–Electrochemical Catalysis

N‐Oxyl Radicals in Oxidative C−O Coupling: Free‐Radical Hydrogen Substitution and Addition to C=C Bonds

Anodisches Recycling von gängigen Polymeren: Die Kombination von Eisen‐Elektrokatalyse und skalierbarer Wasserstoffentwicklungsreaktion

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