Graphitic Carbon Nitride−γ-Gallium Oxide (GCN‑γ-Ga2O3) Nanohybrid Photocatalyst for Dinitrogen Fixation and Pollutant Decomposition

Dinitrogen (N2) is earth’s most abundant form of gas, and its photofixation into ammonia (NH3) is a sustainable solution. Solar-driven photoreduction of N2 to NH3 at ambient temperature and pressure is a benign technique to generate renewable fuels; however, the NH3 production is currently limited t...

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Bibliographic Details
Published in:ACS applied nano materials 2018-10, Vol.1 (10), p.5581-5588
Main Authors: Devthade, Vidyasagar, Gupta, Akanksha, Umare, Suresh S
Format: Article
Language:English
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Summary:Dinitrogen (N2) is earth’s most abundant form of gas, and its photofixation into ammonia (NH3) is a sustainable solution. Solar-driven photoreduction of N2 to NH3 at ambient temperature and pressure is a benign technique to generate renewable fuels; however, the NH3 production is currently limited to noble-metal-containing systems that operate at high pressure and temperature. Herein, we assess the light-driven photoreduction of N2 to NH3 and dye degradation activity of γ-gallium oxide (γ-Ga2O3) hierarchical nanostructures deposited on two-dimensional graphitic carbon nitride (GCN). Using the advantage of surface nitrogen vacancies of GCN and interfacial coupling of GCN-γ-Ga2O3 nanohybrid catalysts, we were able to photoreduce N2 to NH3 under light irradiation at ambient conditions and effectively degrade various organic dyes. The N2 photoreduction using GCN-γ-Ga2O3(10) nanohybrid yielded NH4 + production rate of 355.5 μmol L–1 h–1, which is 1.6-fold and 16-fold higher than GCN and γ-Ga2O3, respectively. The underlying highlights of the hybrid catalyst presents economical route to aqueous-phase N2 reduction into NH3 via heterogeneous photocatalysis under solar light.
ISSN:2574-0970
2574-0970
DOI:10.1021/acsanm.8b01145