Your search keyword '"Structure depended selectivity"' showing total 4 results

1. Structure Dependent Product Selectivity for CO2 Electroreduction on ZnO Derived Catalysts.

Author

Han, Kai, Ngene, Peter, and Jongh, Petra

Subjects

*ELECTROLYTIC reduction, *ZINC oxide, *CATALYST selectivity, *METALLIC oxides, *CATALYSTS, *ZINC catalysts

Abstract

Electrochemical conversion of CO2 is an attractive alternative to releasing it to the atmosphere. Catalysts derived from electroreduction of metal oxides are often more active than when starting with metallic phase catalyst. The origin of this effect is not yet clear. Using ZnO nanorods, we show that the initial structure of the oxide as well as the electrolyte medium have a profound impact on the structure of the catalytic active Zn phase, and thereby the selectivity of the catalysts. ZnO nanorods with various aspect ratios were electrochemically reduced in different electrolytes leading to metallic Zn with different structures; a sponge‐like structure, nanorods and nanoplates. The sponge‐like Zn produced syngas with H2 : CO=2, and some formate, the nanorods produced only syngas with H2 : CO=1, while Zn nanoplates exhibited 85 % selectivity towards CO. These results open a pathway to design new electrocatalysts with optimized properties by modifying the structure of the starting material and the electroreduction medium. [ABSTRACT FROM AUTHOR]

Published

2021

2. Structure Dependent Product Selectivity for CO2 Electroreduction on ZnO Derived Catalysts

Author

Han, Kai, Ngene, Peter, de Jongh, Petra, Han, Kai, Ngene, Peter, and de Jongh, Petra

Abstract

Electrochemical conversion of CO2 is an attractive alternative to releasing it to the atmosphere. Catalysts derived from electroreduction of metal oxides are often more active than when starting with metallic phase catalyst. The origin of this effect is not yet clear. Using ZnO nanorods, we show that the initial structure of the oxide as well as the electrolyte medium have a profound impact on the structure of the catalytic active Zn phase, and thereby the selectivity of the catalysts. ZnO nanorods with various aspect ratios were electrochemically reduced in different electrolytes leading to metallic Zn with different structures; a sponge-like structure, nanorods and nanoplates. The sponge-like Zn produced syngas with H2 : CO=2, and some formate, the nanorods produced only syngas with H2 : CO=1, while Zn nanoplates exhibited 85 % selectivity towards CO. These results open a pathway to design new electrocatalysts with optimized properties by modifying the structure of the starting material and the electroreduction medium.

Published

2021

3. Structure Dependent Product Selectivity for CO 2 Electroreduction on ZnO Derived Catalysts

Author

Kai Han, Petra E. de Jongh, and Peter Ngene

Subjects

Materials science, Structure depended selectivity, CO2 electroreduction, Oxide, ZnO nanorods, 02 engineering and technology, 010402 general chemistry, Electrochemistry, 01 natural sciences, Multiple products, Catalysis, Inorganic Chemistry, Metal, chemistry.chemical_compound, Formate, Physical and Theoretical Chemistry, Full Paper, Organic Chemistry, Reduced Zn phase, Full Papers, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Chemical engineering, visual_art, visual_art.visual_art_medium, Nanorod, 0210 nano-technology, Selectivity, Syngas

Abstract

Electrochemical conversion of CO2 is an attractive alternative to releasing it to the atmosphere. Catalysts derived from electroreduction of metal oxides are often more active than when starting with metallic phase catalyst. The origin of this effect is not yet clear. Using ZnO nanorods, we show that the initial structure of the oxide as well as the electrolyte medium have a profound impact on the structure of the catalytic active Zn phase, and thereby the selectivity of the catalysts. ZnO nanorods with various aspect ratios were electrochemically reduced in different electrolytes leading to metallic Zn with different structures; a sponge‐like structure, nanorods and nanoplates. The sponge‐like Zn produced syngas with H2 : CO=2, and some formate, the nanorods produced only syngas with H2 : CO=1, while Zn nanoplates exhibited 85 % selectivity towards CO. These results open a pathway to design new electrocatalysts with optimized properties by modifying the structure of the starting material and the electroreduction medium., The structure to evolve: Electron micrographs illustrates the evolution of Zn structure from the electroreduction of ZnO nanorods, and the effects on the product selectivity in the CO2 electroreduction. This work shows that the structure/morphology, and hence product selectivity of oxide‐derived Zn catalysts in CO2 electroreduction, can be tuned by changing the structure/aspect ratio of the staring ZnO nanorods and the reduction condition.

Published

2021

4. Structure Dependent Product Selectivity for CO 2 Electroreduction on ZnO Derived Catalysts.

Author

Han K, Ngene P, and de Jongh P

Abstract

Electrochemical conversion of CO 2 is an attractive alternative to releasing it to the atmosphere. Catalysts derived from electroreduction of metal oxides are often more active than when starting with metallic phase catalyst. The origin of this effect is not yet clear. Using ZnO nanorods, we show that the initial structure of the oxide as well as the electrolyte medium have a profound impact on the structure of the catalytic active Zn phase, and thereby the selectivity of the catalysts. ZnO nanorods with various aspect ratios were electrochemically reduced in different electrolytes leading to metallic Zn with different structures; a sponge-like structure, nanorods and nanoplates. The sponge-like Zn produced syngas with H 2  : CO=2, and some formate, the nanorods produced only syngas with H 2  : CO=1, while Zn nanoplates exhibited 85 % selectivity towards CO. These results open a pathway to design new electrocatalysts with optimized properties by modifying the structure of the starting material and the electroreduction medium., Competing Interests: The authors declare no conflict of interest., (© 2021 The Authors. ChemCatChem published by Wiley-VCH GmbH.)

Published

2021