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Hydrogenated borophene enabled synthesis of multielement intermetallic catalysts.

Xiaoxiao ZengYudan JingSaisai GaoWencong ZhangYang ZhangHanwen LiuChao LiangChenchen JiYi RaoJian-Bo WuBin WangYonggang YaoShengchun Yang
Published in: Nature communications (2023)
Supported metal catalysts often suffer from rapid degradation under harsh conditions due to material failure and weak metal-support interaction. Here we propose using reductive hydrogenated borophene to in-situ synthesize Pt/B/C catalysts with small sizes (~2.5 nm), high-density dispersion (up to 80 wt% Pt ), and promising stability, originating from forming Pt-B bond which are theoretically ~5× stronger than Pt-C. Based on the Pt/B/C module, a series (~18 kinds) of carbon supported binary, ternary, quaternary, and quinary Pt intermetallic compound nanocatalysts with sub-4 nm size are synthesized. Thanks to the stable intermetallics and strong metal-support interaction, annealing at 1000 °C does not cause those nanoparticles sintering. They also show much improved activity and stability in electrocatalytic oxygen reduction reaction. Therefore, by introducing the boron chemistry, the hydrogenated borophene derived multielement catalysts enable the synergy of small size, high loading, stable anchoring, and flexible compositions, thus demonstrating high versatility toward efficient and durable catalysis.
Keyphrases
  • highly efficient
  • high density
  • transition metal
  • metal organic framework
  • gold nanoparticles