Photovoltaic-driven Ni()/Ni() redox mediator for the valorization of PET plastic waste with hydrogen production

Electrocatalytic valorization of PET plastic waste provides an appealing route by converting intermittent renewable energy into valuable chemicals and high-energy fuels. Normally, anodic PET hydrolysate oxidation and cathodic water reduction reactions occur simultaneously in the same time and space,...

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Veröffentlicht in:	Chemical science (Cambridge) 2024-05, Vol.15 (2), p.7596-762
Hauptverfasser:	Wang, Jianying, Li, Xin, Zhang, Ting, Chai, Xinyu, Xu, Mingze, Feng, Menglei, Cai, Chengcheng, Chen, Zuofeng, Qian, Xufang, Zhao, Yixin
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Sprache:	eng
Schlagworte:	Anodizing Chemical reactions Chemical reduction Chemistry Decoupling Diaphragms Electrodes Formic acid High energy fuels Hydrogen fuels Hydrogen production Hydrolysates Membranes Oxidation Purity
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container_title	Chemical science (Cambridge)
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creator	Wang, Jianying Li, Xin Zhang, Ting Chai, Xinyu Xu, Mingze Feng, Menglei Cai, Chengcheng Chen, Zuofeng Qian, Xufang Zhao, Yixin
description	Electrocatalytic valorization of PET plastic waste provides an appealing route by converting intermittent renewable energy into valuable chemicals and high-energy fuels. Normally, anodic PET hydrolysate oxidation and cathodic water reduction reactions occur simultaneously in the same time and space, which increases the challenges for product separation and operational conditions. Although these problems can be addressed by utilizing membranes or diaphragms, the parasitic cell resistance and high overall cost severely restrict their future application. Herein, we introduce a Ni( ii )/Ni( iii ) redox mediator to decouple these reactions into two independent processes: an electrochemical process for water reduction to produce hydrogen fuel assisted by the oxidation of the Ni(OH) 2 electrode into the NiOOH counterpart, followed subsequently by a spontaneous chemical process for the valorization of PET hydrolysate to produce formic acid with a high faradaic efficiency of ∼96% by the oxidized NiOOH electrode. This decoupling strategy enables the electrochemical valorization of PET plastic waste in a membrane-free system to produce high-value formic acid and high-purity hydrogen production. This study provides an appealing route to facilitate the transformation process of PET plastic waste into high-value products with high efficiency, low cost and high purity. A decoupling strategy involving two independent electrochemical and chemical processes was developed for upcycling PET plastic waste.
doi_str_mv	10.1039/d4sc01613k
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This decoupling strategy enables the electrochemical valorization of PET plastic waste in a membrane-free system to produce high-value formic acid and high-purity hydrogen production. This study provides an appealing route to facilitate the transformation process of PET plastic waste into high-value products with high efficiency, low cost and high purity. 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subjects	Anodizing Chemical reactions Chemical reduction Chemistry Decoupling Diaphragms Electrodes Formic acid High energy fuels Hydrogen fuels Hydrogen production Hydrolysates Membranes Oxidation Purity
title	Photovoltaic-driven Ni()/Ni() redox mediator for the valorization of PET plastic waste with hydrogen production
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