As one of the best candidates for hydrogen oxidation reaction (HOR), ruthenium (Ru) has attracted significant attention for anion exchange membrane fuel cells (AEMFCs), although it suffers from sluggish kinetics under alkaline conditions due to its strong hydroxide affinity. In this work, we develop ternary hollow nanocages with Pt epitaxy on RuCu (Pt-RuCu NCs) as efficient HOR catalysts for application in AEMFCs. Experimental characterizations and theoretical calculations confirm that the synergy in optimized Pt8.7-RuCu NCs significantly modifies the electronic structure and coordination environment of Ru, thereby balancing the binding strengths of H* and OH* species, which leads to a markedly enhanced HOR performance. Specifically, the optimized Pt8.7-RuCu NCs/C achieves a mass activity of 5.91 A mgPt+Ru-1, which is ~3.3, ~2.2, and ~15.0 times higher than that of RuCu NCs/C (1.38 A mgRu-1), PtRu/C (1.83 A mgPt+Ru-1) and Pt/C (0.37 A mgPt-1), respectively. Impressively, the specific peak power density of fuel cells reaches 15.9 W mgPt+Ru-1, significantly higher than those of most reported PtRu-based fuel cells.
Keywords: AEMFC; Galvanic replacement; Hydrogen adsorption; Hydrogen oxidation reaction; Hydroxide adsorption.
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