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Atomic tuning of 3D printed carbon surface chemistry for electrocatalytic nitrite oxidation and reduction to ammonia

Nitrite contamination in agricultural and industrial wastewater presents a critical impact on environmental sustainability, demanding efficient strategies for monitoring and remediation. This study addresses this challenge by developing cost-effective electrocatalysts for both nitrite detection and...

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Bibliographic Details
Published in:	Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2024-11, Vol.12 (46), p.32458-3247
Main Authors:	Gao, Wanli, Michali ka, Jan, Pumera, Martin
Format:	Article
Language:	English
Subjects:	Agricultural pollution Agricultural wastes Ammonia Atomic layer epitaxy Carbon Carbon nanotubes Carbon sources Chemical activity Chemical reduction Electrocatalysts Electrochemistry Electrodes Environmental impact Environmental monitoring Fabrication Impurities Industrial pollution Industrial wastes Industrial wastewater Nanotechnology Nanotubes Nitrites Oxidation Substrates Surface chemistry Three dimensional printing Titanium dioxide Wastewater treatment
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Summary:	Nitrite contamination in agricultural and industrial wastewater presents a critical impact on environmental sustainability, demanding efficient strategies for monitoring and remediation. This study addresses this challenge by developing cost-effective electrocatalysts for both nitrite detection and conversion to value-added ammonia. 3D printed carbon materials are explored as bifunctional platforms for the electrochemical nitrite oxidation reaction (NO 2 OR) and nitrite reduction reaction (NO 2 RR). Benefiting from the inherent Ti-dominated metallic impurities and intrinsic surface features of carbon nanotubes, 3D printed carbon electrodes exhibit electrocatalytic activity for both reactions. To enhance this activity, we further introduce an effective fabrication methodology that combines 3D printing of carbon substrates with precise surface modification using atomic layer deposition (ALD) of TiO 2 . The resulting TiO 2 -coated carbon electrode demonstrates significantly improved electrocatalytic properties. For NO 2 OR, it exhibits a peak current density of 0.75 mA cm −2 at 1.53 V vs. RHE, while for NO 2 RR, it achieves a yield rate of 630.5 µg h −1 cm −2 with a faradaic efficiency of 81.9% at −1.06 V vs. RHE. This enhancement in electrocatalytic activity is primarily attributed to the formation of abundant interfaces between the conductive carbon and ALD-coated TiO 2 . The developed methodology not only enables precise modification of 3D printed carbon surface chemistry but also presents a scalable method for electrocatalyst production. A bifunctional electrode integrating 3D printed carbon materials with atomic layer deposition of TiO 2 is developed for electrochemical nitrite oxidation and reduction, providing effective surface engineering for nitrite monitoring and remediation.
ISSN:	2050-7488 2050-7496
DOI:	10.1039/d4ta06800a