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Synergistic enhancement of H2 and CH4 evolution by CO2 photoreduction in water with reduced Graphene oxide–bismuth monoxide quantum dot catalyst

Sun, Songmei, Watanabe, Motonori, Wang, Pangpang and Ishihara, Tatsumi 2019. Synergistic enhancement of H2 and CH4 evolution by CO2 photoreduction in water with reduced Graphene oxide–bismuth monoxide quantum dot catalyst. ACS Applied Energy Materials 2 (3) , pp. 2104-2112. 10.1021/acsaem.8b02153

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Abstract

Photocatalytic water splitting or CO2 reduction is one of the most promising strategies for solar energy conversion into hydrogen-containing fuels. However, these two processes typically compete with each other, which significantly decreases the solar energy conversion efficiency. Herein, we report for the first time this competition can be overcome by modulation of reactive sites and electron transfer pathway of heterogeneous photocatalysts. As a prototype, BiO composite reduced graphene oxide quantum dots (RGO-BiO QDs) were synthesized, which can provide large amounts of photogenerated electrons as well as individual reactive sites for H+ and CO2 reduction. The productivity of H2, CH4, and CO by the RGO-BiO QDs catalyst were 102.5, 21.75, and 4.5 μmol/(g·h), respectively, in pure water without the assistance of any cocatalyst or sacrificial agent. The apparent quantum efficiency at 300 nm reached to 4.2%, which is more than 10 times higher than that of RGO-TiO2 QDs (0.28%) under the same conditions. In situ DRIFT, ESR, and photoelectrochemical studies confirmed that the unique circled electron transfer pathway (Evb(BiO) → Ecb(BiO) → Ef(RGO) → EVo•(BiO)) and the large amount of separated different reactive sites are responsible for the highly efficient simultaneous H2 evolution and CO2 reduction performance.

Item Type: Article
Date Type: Publication
Status: Published
Schools: Chemistry
Publisher: American Chemical Society
ISSN: 2574-0962
Date of First Compliant Deposit: 22 May 2019
Date of Acceptance: 22 February 2019
Last Modified: 06 Nov 2023 14:38
URI: https://orca.cardiff.ac.uk/id/eprint/122045

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