NAME

Jijun Zhao

Paper Publications

Boosting electrocatalytic oxygen evolution by synergistically coupling layered double hydroxide with MXene
  • Hits:
  • Indexed by:

    期刊论文

  • First Author:

    Yu, Mengzhou

  • Correspondence Author:

    Wang, ZY; Qiu, JS (reprint author), Dalian Univ Technol, State Key Lab Fine Chem, Liaoning Key Lab Energy Mat & Chem Engn, PSU DUT Joint Ctr Energy Res, Dalian 116024, Peoples R China.

  • Co-author:

    Zhou, Si,Wang, Zhiyu,Zhao, Jijun,Qiu, Jieshan

  • Date of Publication:

    2018-02-01

  • Journal:

    NANO ENERGY

  • Included Journals:

    ESI高被引论文、SCIE、EI

  • Document Type:

    J

  • Volume:

    44

  • Page Number:

    181-190

  • ISSN No.:

    2211-2855

  • Key Words:

    MXene; Layered double hydroxide; Nanohybrids; Electrocatalyst; Oxygen evolution reaction

  • Abstract:

    Oxygen evolution reaction (OER) is cornerstone reaction of many renewable energy technologies. Cost-effective yet efficient electrocatalysts are critical to overcome the high overpotential and sluggish kinetics of this process. The development of efficient non-precious metal catalysts is one of the crucial but very challenging steps to this end. Herein, we report a new type of non-precious metal electrocatalyst for OER by synergistically coupling layered double hydroxides (LDH) with two-dimensional (2D) MXene with high conductivity and active surface. Hierarchical FeNi-LDH/Ti3C2-MXene nanohybrids with excellent structural stability, electrical properties and interfacial junction are fabricated by ionic hetero-assembly of interconnected porous network of FeNi-LDH nanoplates on Ti3C2 MXene nanosheets. Strong interfacial interaction and electronic coupling with prominent charge-transfer between the FeNi-LDH and Ti3C2 MXene is identified, which not only improves the structural stability and electrical conductivity of the nanohybrids, but also greatly accelerates the redox process of FeNi-LDH for OER. As a result, the FeNi-LDH/Ti3C2-MXene catalyst could exhibit superior activity, reaction kinetics and durability to RuO2 and its graphene-based counterpart for OER in alkaline medium. This work may pave the way on the development of a new branch of advanced electrocatalysts for renewable energy applications.

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