Your search keyword '"Huang, Shaoda"' showing total 3 results

1. Bimetallic palladium-copper nanoplates with optimized d-band center simultaneously boost oxygen reduction activity and methanol tolerance.

Author

Huang, Shaoda, Wang, Jinyan, Hu, Hongyin, Li, Yang, Xu, Fangping, Duan, Fang, Zhu, Han, Lu, Shuanglong, and Du, Mingliang

Subjects

*OXYGEN reduction, *DIRECT methanol fuel cells, *METHANOL, *OXIDATION of methanol, *METHANOL as fuel

Abstract

A simple strategy is developed for synthesis of PdCu nanoplates as efficient ORR electrocatalysts with simultaneously highly methanol tolerance. [Display omitted] The methanol-poisoning of electrocatalysts at the cathodic part of direct methanol fuel cells (DMFCs) can severely degrade the overall efficiency. Therefore, engineering cathodic catalysts with outstanding oxygen reduction activity, and simultaneously, superior methanol tolerance is greatly desired. Herein, bimetallic palladium-copper (PdCu) nanoplates with the optimized d-band center are designed as promising cathodic catalysts for DMFCs. It shows outstanding oxygen reduction activity with a mass activity (MA) of 0.522 A mg Pd −1 in alkaline electrolyte, overwhelming the benchmarked commercial Pt/C and Pd/C. Meanwhile, it has prominent stability with only 4.0 % loss in MA after continuous 20 K cycles. More importantly, the PdCu nanoplates are almost inert toward methanol oxidation and show excellent anti-methanol capability. The theoretical calculations reveal that the downshift of d-band center in PdCu nanoplates and the electronic interaction between Pd and Cu atoms could effectively lower the methanol adsorption energy, thus leading to enhanced methanol tolerance. This work highlights the important role of tuning the electronic structure and optimized geometry of electrocatalysts to simultaneously boost their oxygen reduction activity, stability, and methanol tolerance for their future application in DMFCs. [ABSTRACT FROM AUTHOR]

Published

2023

2. Bimetallic palladium-copper nanoplates with optimized d-band center simultaneously boost oxygen reduction activity and methanol tolerance.

Author

Huang, Shaoda, Wang, Jinyan, Hu, Hongyin, Li, Yang, Xu, Fangping, Duan, Fang, Zhu, Han, Lu, Shuanglong, and Du, Mingliang

Subjects

*OXYGEN reduction, *DIRECT methanol fuel cells, *METHANOL, *OXIDATION of methanol, *METHANOL as fuel

Abstract

A simple strategy is developed for synthesis of PdCu nanoplates as efficient ORR electrocatalysts with simultaneously highly methanol tolerance. [Display omitted] The methanol-poisoning of electrocatalysts at the cathodic part of direct methanol fuel cells (DMFCs) can severely degrade the overall efficiency. Therefore, engineering cathodic catalysts with outstanding oxygen reduction activity, and simultaneously, superior methanol tolerance is greatly desired. Herein, bimetallic palladium-copper (PdCu) nanoplates with the optimized d-band center are designed as promising cathodic catalysts for DMFCs. It shows outstanding oxygen reduction activity with a mass activity (MA) of 0.522 A mg Pd −1 in alkaline electrolyte, overwhelming the benchmarked commercial Pt/C and Pd/C. Meanwhile, it has prominent stability with only 4.0 % loss in MA after continuous 20 K cycles. More importantly, the PdCu nanoplates are almost inert toward methanol oxidation and show excellent anti-methanol capability. The theoretical calculations reveal that the downshift of d-band center in PdCu nanoplates and the electronic interaction between Pd and Cu atoms could effectively lower the methanol adsorption energy, thus leading to enhanced methanol tolerance. This work highlights the important role of tuning the electronic structure and optimized geometry of electrocatalysts to simultaneously boost their oxygen reduction activity, stability, and methanol tolerance for their future application in DMFCs. [ABSTRACT FROM AUTHOR]

Published

2023

3. A stable PdCu@Pd core-shell nanobranches with enhanced activity and methanol-tolerant for oxygen reduction reaction.

Author

Huang, Shaoda, Lu, Shuanglong, Hu, Hongyin, Cao, Binbin, Li, Huining, Duan, Fang, Zhu, Han, Gu, Hongwei, and Du, Mingliang

Subjects

*OXYGEN reduction, *CATALYSTS, *SURFACE structure, *NANOCRYSTALS, *NANOSTRUCTURED materials

Abstract

Palladium-based catalyst represents one of the most promising candidates among all non-platinum oxygen reduction reaction (ORR) catalysts. However, it is still challenging to precisely engineering their morphology and composition. Herein, highly branched core-shell PdCu@Pd nanocrystals have been fabricated via a simple one-pot synthesis that co-directed by hydrogen gas and halide ions. Such unique PdCu@Pd nanocrystals exhibit prominent ORR activity, durability and methanol-tolerance in alkaline media owing to their core-shell composition, highly-branched structure and defect-rich surface. This work elucidates a facile strategy to design highly branched core-shell nanomaterials, shedding light on the exploration and optimization of novel non-platinum ORR catalysts. A facile method for one-pot synthesis of Defect-rich PdCu@Pd Core-shell Nanobranches is developed. The as-made catalyst shows superior activity, durability and methanol-tolerance towards oxygen reduction reaction. Image 1 [ABSTRACT FROM AUTHOR]

Published

2020