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Manipulating Photoconduction in Supramolecular Networks for Solar-Driven Nitrate Conversion to Ammonia and Oxygen

Feiyang Hong, Xinhao Su, Yanjie Fang, Xinjia He, Bing Shan

2024Journal of the American Chemical Society23 citationsDOI

Abstract

For photoelectrodes to be used in practical catalytic applications, challenges exist in achieving the efficient production and transport of photogenerated charge-separated states. Analogous concepts in traditional inorganic photoelectrodes can be applied to their organic-polymer counterparts with improved charge-separation efficiencies. In this work, we develop photoconductive organic networks to form a high-performance photoelectrode for NO 3 – reduction to NH 3 . In the integrated network, interfaces between the organic electron-donating photoconductor and electron-accepting catalyst can generate charge carriers efficiently upon illumination, leading to enhanced charge separation for photoelectrocatalysis. The photoelectrode network is capable of converting NO 3 – to NH 3 at an external quantum efficiency of 13%. By coupling with a BiVO 4 photoanode in tandem, the system reduces NO 3 – to NH 3 and oxidizes H 2 O to O 2 simultaneously at Faradaic efficiencies of 95–98% with sustained photocurrents and production yields. Investigation of the photoconductive network by steady-state/time-resolved spectroscopies reveals the efficient generation and transport of free charge carriers in the photoelectrode, providing a basis for high photoelectrocatalytic performances.

Topics & Concepts

ChemistryAmmoniaNitrateSupramolecular chemistryOxygenPhotochemistryInorganic chemistryMoleculeOrganic chemistryAdvanced Photocatalysis TechniquesCovalent Organic Framework ApplicationsPerovskite Materials and Applications
Manipulating Photoconduction in Supramolecular Networks for Solar-Driven Nitrate Conversion to Ammonia and Oxygen | Litcius