Affiliation:
1. Huangpu Hydrogen Energy Innovation Centre/School of Chemistry and Chemical Engineering Guangzhou University Wai Huan Xi Road 230 Guangzhou 510006 P. R. China
2. College of Chemical and Biological Engineering Zhejiang University Yuhangtang Road Hangzhou 310058 P. R. China
3. SinoHykey Technology Company Ltd. 8 Hongyuan Road, Huangpu District Guangzhou 510760 P. R. China
Abstract
AbstractRecently, coupling the conventional low Pt‐group‐metal (low‐PGM, LP) and emerging PGM‐free (PF) moiety to form a composite LP/PF catalyst is proposed to be an advanced strategy to improve the intrinsic activity and stability of oxygen reduction reaction (ORR) catalysts. Milestones in terms of ORR mass activity are created by this type of catalyst. However, the specific synergy between LP and PF moieties has not been well elucidated. Herein, two model catalysts are synthesized, i.e., atomically dispersed Co/N/C supporting Pt single atoms (Co/N/C@Pt‐SAs) and PtCo nanoparticles (Co/N/C@PtCo‐NPs). Interestingly, the Co/N/C@PtCo‐NPs catalyst presents higher ORR mass activity prior to Co/N/C@Pt‐SAs. This is theoretically due to the dual “built‐in electric field” in Co/N/C@PtCo‐NPs: one electric field with a direction from Pt to Co in NPs and another from Pt to Co/N/C; that is, Pt gains higher electron density in Co/N/C@PtCo‐NPs than that in Co/N/C@Pt‐SAs, thus forming an asymmetric electron cloud, and regulating the adsorption and activation of oxygen‐containing species. In addition, the existence of Co significantly decreases the average valence state of PtCo NPs, indicating a stronger affinity between PtCo NPs and Co/N/C substrate, to account for the enhanced stability.
Funder
National Natural Science Foundation of China
Natural Science Foundation of Guangdong Province
Basic and Applied Basic Research Foundation of Guangdong Province
Reference54 articles.
1. Recent Advances on PEM Fuel Cells: From Key Materials to Membrane Electrode Assembly
2. D.Papageorgopoulos in“Fuel Cell R&D Overview. U.S. DOE Annual Merit Review and Peer Evaluation Meeting” can be found under https://www.hydrogen.energy.gov/pdfs/review19/plenary_fuel_cell_papageorgopoulos_2019.pdf (accessed: April 2019).
3. S.Katayama in“Characterization and analysis on the new generation Mirai catalysts (in Japanese)” can be found under http://fc‐cubic‐event.jp/wp‐sympo/wp‐content/uploads/2022/05/bb54e72f169dae5e5c564288d6405f16.pdf 2021.
4. Amino-tethering synthesis strategy toward highly accessible sub-3-nm L10-PtM catalysts for high-power fuel cells
5. Active and Stable Pt–Ni Alloy Octahedra Catalyst for Oxygen Reduction via Near-Surface Atomical Engineering