Royal Society Open Science (Jan 2017)

From two-dimensional graphene oxide to three-dimensional honeycomb-like Ni3S2@graphene oxide composite: insight into structure and electrocatalytic properties

  • Xinting Wei,
  • Yueqiang Li,
  • Wenli Xu,
  • Kaixuan Zhang,
  • Jie Yin,
  • Shaozhen Shi,
  • Jiazhen Wei,
  • Fangfang Di,
  • Junxue Guo,
  • Can Wang,
  • Chaofan Chu,
  • Ning Sui,
  • Baoli Chen,
  • Yingtian Zhang,
  • Hongguo Hao,
  • Xianxi Zhang,
  • Jinsheng Zhao,
  • Huawei Zhou,
  • Shuhao Wang

DOI
https://doi.org/10.1098/rsos.171409
Journal volume & issue
Vol. 4, no. 12

Abstract

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Three-dimensional (3D) graphene composites have drawn increasing attention in energy storage/conversion applications due to their unique structures and properties. Herein, we synthesized 3D honeycomb-like Ni3S2@graphene oxide composite (3D honeycomb-like Ni3S2@GO) by a one-pot hydrothermal method. We found that positive charges of Ni2+ and negative charges of NO3− in Ni(NO3)2 induced a transformation of graphene oxide with smooth surface into graphene oxide with wrinkled surface (w-GO). The w-GO in the mixing solution of Ni(NO3)2/thioacetamide/H2O evolved into 3D honeycomb-like Ni3S2@GO in solvothermal process. The GO effectively inhibited the aggregation of Ni3S2 nanoparticles. Photoelectrochemical cells based on 3D Ni3S2@GO synthesized at 60 mM l−1 Ni(NO3)2 exhibited the best energy conversion efficiency. 3D Ni3S2@GO had smaller charge transfer resistance and larger exchange current density than pure Ni3S2 for iodine reduction reaction. The cyclic stability of 3D honeycomb-like Ni3S2@GO was good in the iodine electrolyte. Results are of great interest for fundamental research and practical applications of 3D GO and its composites in solar water-splitting, artificial photoelectrochemical cells, electrocatalysts and Li-S or Na-S batteries.

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