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Mo Doping Induced More Active Sites in Urchin‐Like W 18 O 49 Nanostructure with Remarkably Enhanced Performance for Hydrogen Evolution Reaction
Author(s) -
Zhong Xing,
Sun Youyi,
Chen Xianlang,
Zhuang Guilin,
Li Xiaonian,
Wang JianGuo
Publication year - 2016
Publication title -
advanced functional materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 6.069
H-Index - 322
eISSN - 1616-3028
pISSN - 1616-301X
DOI - 10.1002/adfm.201601732
Subject(s) - tafel equation , materials science , overpotential , nanostructure , electrochemistry , dopant , catalysis , nanowire , water splitting , density functional theory , doping , hydrogen , nanotechnology , electron transfer , chemical engineering , electrode , electrochemical energy conversion , chemical physics , chemistry , optoelectronics , computational chemistry , organic chemistry , photocatalysis , engineering
Exploring highly efficient and inexpensive hydrogen evolution reaction (HER) electrocatalysts for various electrochemical energy conversion technologies is actively encouraged. Herein, a 3D urchin‐like Mo‐W 18 O 49 nanostructure as an efficient HER catalyst is reported for the first time. The obtained Mo‐W 18 O 49 catalyst exhibits excellent electrocatalytic activity toward HER with small onset potential and Tafel slope. The prepared Mo‐W 18 O 49 electrode shows excellent durability after a long period. Density functional theory calculations reveal that the remarkably enhanced performance of Mo‐W 18 O 49 can be due to the ability of Mo dopant to increase the number of active sites, leading to optimal hydrogen adsorption on the active sites because of the electronic and geometric modulation. In addition, the urchin‐like 3D morphology with a high surface area and abundant 1D nanowires promotes electron transfer, thereby ensuring fast interfacial charge transfer to improve electrocatalytic reactions. All these experimental and theoretical results clearly reveal that Mo‐W 18 O 49 intrinsically improves HER activity and thus has potential applications in water splitting.