过电位
纳米团簇
塔菲尔方程
动力学
碱性水电解
电解
化学工程
氢
材料科学
化学
电解水
催化作用
无机化学
热化学
制氢
纳米颗粒
纳米技术
金属
反应机理
作者
Ahmed Badreldin,Jin Feng,Shiwen Wu,Shaoqin Chen,Carter Racine,Shengyao Wang,Gabby Smith,Mohammad Bilal Minhas,Tao Li,Yun Hang Hu,Ying Li
标识
DOI:10.1016/j.cej.2026.173234
摘要
The development of efficient, durable, and low-PGM electrocatalysts for the hydrogen evolution reaction (HER) in alkaline media is critical for next-generation electrolysis technologies. We report a facile two-step synthesis of highly dispersed PtNi and PtNi-nitride nanoclusters (NCs) (~2.3 nm) with ultralow Pt content (0.5 at.%) anchored on N-doped Vulcan carbon. Structural and compositional characterization via XAS, XPS, HAADF-STEM, HRTEM, and EDS mapping established key structure–activity relationships across varying Pt/Ni ratios and pyrolysis temperatures. The Pt 0.5 Ni 0.5 /C-750 catalyst, an ensemble of PtNi M-N-C type single-atom (SA) moieties with neighboring PtNi nanoclusters (NC), exhibited superior HER performance in alkaline media, achieving overpotentials of 30, 115, and 210 mV at 10, 100, and 500 mA cm −2 , respectively. Despite at a lower Pt content, this novel SA–NC ensemble outperformed commercial Pt/C by ~36%. A standardized literature comparison with contemporary Pt- or Ru-doped analogues reveals the as-prepared Pt 0.5 Ni 0.5 /C-750 to sit at the apex of Tafel-limited kinetics and low overpotential at 100 mA cm −2 . Tafel-limited Tafel slopes in both alkaline and acidic regimes confirm favorable proton recombination kinetics. Mass activities at 200 mV reached 13.8 and 18.84 A mg Pt −1 in alkaline and acidic media, respectively. However, excessive nitridation (e.g., at 650 °C) adversely altered Pt electronic structure and HER kinetics. While Ni enhanced alkaline HER, acidic HER favored Ni-free analogues. Pt 0.5 Ni 0.5 /C-750 also demonstrated robust temperature responsiveness and 300-h operational stability at high current densities (0.5–1.0 A cm −2 ) in MEA tests. This work presents a scalable strategy for designing thermally responsive, durable, and compositionally tunable NC catalysts with neighboring SA moieties for alkaline electrolysis. • A facile method to synthesize single-atom–nanocluster (SA–NC) ensembles on N-doped carbon • SA sites facilitate water dissociation and nearby NC sites promote H* recombination. • Ultralow-PGM PtNi NCs achieve 36% higher alkaline HER activity than Pt/C. • 300 h stability at 0.5–1.0 A cm −2 in 5 cm 2 AEMWE without performance loss • Alkaline HER activity and kinetics depend on synergistic SA–NC proximity and composition.
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