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Engineering the Low Coordinated Pt Single Atom to Achieve the Superior Electrocatalytic Performance toward Oxygen Reduction.

Zhongxin SongYa-Nan ZhuHanshuo LiuMohammad Norouzi BanisLei ZhangJunjie LiKieran Doyle-DavisRuying LiTsun-Kong ShamLijun YangAlan YoungGianluigi A BottonLi-Min LiuXueliang Sun
Published in: Small (Weinheim an der Bergstrasse, Germany) (2020)
Configuring metal single-atom catalysts (SACs) with high electrocatalytic activity and stability is one efficient strategy in achieving the cost-competitive catalyst for fuel cells' applications. Herein, the atomic layer deposition (ALD) strategy for synthesis of Pt SACs on the metal-organic framework (MOF)-derived N-doped carbon (NC) is proposed. Through adjusting the ALD exposure time of the Pt precursor, the size-controlled Pt catalysts, from Pt single atoms to subclusters and nanoparticles, are prepared on MOF-NC support. X-ray absorption fine structure spectra determine the increased electron vacancy in Pt SACs and indicate the Pt-N coordination in the as-prepared Pt SACs. Benefiting from the low-coordination environment and anchoring interaction between Pt atoms and nitrogen-doping sites from MOF-NC support, the Pt SACs deliver an enhanced activity and stability with 6.5 times higher mass activity than that of Pt nanoparticle catalysts in boosting the oxygen reduction reaction (ORR). Density functional theory calculations indicate that Pt single atoms prefer to be anchored by the pyridinic N-doped carbon sites. Importantly, it is revealed that the electronic structure of Pt SAs can be adjusted by adsorption of hydroxyl and oxygen, which greatly lowers free energy change for the rate-determining step and enhances the activity of Pt SACs toward the ORR.
Keyphrases
  • metal organic framework
  • density functional theory
  • highly efficient
  • molecular dynamics
  • magnetic resonance imaging
  • magnetic resonance
  • quantum dots
  • mass spectrometry
  • cell death
  • room temperature