Cobalt-doped CdS quantum dots enhanced photoelectroreduction of CO2 to formic acid with high selectivity

Excessive carbon dioxide (CO 2 ) emission has caused problems associated with environmental pollution and climate deterioration. As a consequence, the selective conversion of CO 2 into liquid fuels by artificial photosynthesis has gained increasing attention. However, the rational design of photocat...

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Bibliographic Details
Published in:Environmental chemistry letters 2024-04, Vol.22 (2), p.463-470
Main Authors: Liu, Shengqi, Guo, Zhenyan, Yang, Ying, Wu, Pei-dong, Li, Zhengyi, Wang, Keping, Zhang, Heng, Li, Hu, Yang, Song
Format: Article
Language:English
Subjects:
absorption
Analytical Chemistry
Cadmium
Cadmium sulfide
Carbon dioxide
cathodes
climate
Cobalt
Copper oxides
cuprous oxide
Doping
Earth and Environmental Science
Ecotoxicology
Electrodeposition
Electrons
electroplating
Energy
Energy bands
Energy levels
Environment
Environmental Chemistry
Ferric hydroxide
Formic acid
Geochemistry
Hybridization
Iron oxides
light
Liquid fuels
liquids
Original Article
photocatalysis
Photocathodes
Photosynthesis
Pollution
Quantum dots
Selectivity
Sulphides
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Summary:Excessive carbon dioxide (CO 2 ) emission has caused problems associated with environmental pollution and climate deterioration. As a consequence, the selective conversion of CO 2 into liquid fuels by artificial photosynthesis has gained increasing attention. However, the rational design of photocathode to achieve selective CO 2 photoelectroreduction is challenging. Here, we sensitized cuprous oxide (p-nCu 2 O) loaded on hydroxyl iron oxide (FeOOH) with cobalt-doped cadmium sulfide (Co:CdS) quantum dots to prepare a novel photocathode FeOOH/p-nCu 2 O/Co:CdS by sequential electrodeposition and chemical bath deposition. The composite photocathode exhibited a larger photovoltage, which is 1.9 times higher than the pristine counterpart, and was efficient for CO 2 reduction to produce formic acid with high selectivity of up to 82.9% (Faradaic efficiency). Theoretical calculations revealed that the photocathode out-layer Co:CdS quantum dots had increased binding energy toward the key intermediate *OOCH through additional hybridization orbitals to exclusively favor the formation of formic acid. An impurity energy level was revealed to form by doping Co to the CdS-containing composite, which could reduce the photocathode band gap with improved absorption toward visible light, thus remarkably increasing the photoelectrochemical properties. This is the first work undertaking the energy band structure optimization of the photocathode enabled by elemental doping to improve its photoelectrocatalytic performance.
ISSN:1610-3653
1610-3661
DOI:10.1007/s10311-023-01691-2