Ni-Cos2 Nanoparticles Loaded on 3d Rgo for Efficient Electrochemical Hydrogen and Oxygen Evolution Reaction

34 Pages Posted: 17 Sep 2024

See all articles by Hualan Luo

Hualan Luo

affiliation not provided to SSRN

Shenqi Wei

affiliation not provided to SSRN

Pingxing Xing

affiliation not provided to SSRN

Yuanyuan Wang

affiliation not provided to SSRN

Liyi Dai

affiliation not provided to SSRN

Abstract

The development of efficient non-precious metal electrocatalysts for electrochemical splitting of water is still a huge challenge. In this study, we designed and synthesized an efficient hydrogen evolution and oxygen evolution bifunctional electrocatalyst for Ni-doped cobalt sulfide supported on 3D RGO (Ni-CoS2/3D RGO) using a simple one-step solvent-thermal method. Ni doping adjusted the charge distribution on the surface of the material, significantly improved the catalytic activity, and then accelerated the reaction kinetics. The high specific surface area and high stability of 3D RGO greatly improved the intrinsic activity of the material, making Ni-CoS2/3D RGO exhibit superior catalytic activity in both electrochemical hydrogen evolution and oxygen evolution. When the current density is 10 mA cm-2, the HER overpotential of Ni-CoS2/3D RGO under acidic condition reaches 138 mV, and the Tafel slope is 61mV dec-1. Under alkaline conditions, the OER overpotential reaches 286 mV, and the Tafel slope is only 48 mV dec-1. This work provides a new idea for the application of 3D reduced graphene oxide in electrochemical direction, and also provides a new strategy for the design and preparation of non-precious metal catalysts for the efficient electrochemical hydrogen and oxygen evolution reaction.

Keywords: three-dimensional graphene, hydrogen evolution reaction, oxygen evolution reactions, Electrocatalysis

Suggested Citation

Luo, Hualan and Wei, Shenqi and Xing, Pingxing and Wang, Yuanyuan and Dai, Liyi, Ni-Cos2 Nanoparticles Loaded on 3d Rgo for Efficient Electrochemical Hydrogen and Oxygen Evolution Reaction. Available at SSRN: https://ssrn.com/abstract=4958710 or http://dx.doi.org/10.2139/ssrn.4958710

Hualan Luo

affiliation not provided to SSRN ( email )

No Address Available

Shenqi Wei

affiliation not provided to SSRN ( email )

No Address Available

Pingxing Xing

affiliation not provided to SSRN ( email )

No Address Available

Yuanyuan Wang (Contact Author)

affiliation not provided to SSRN ( email )

No Address Available

Liyi Dai

affiliation not provided to SSRN ( email )

No Address Available

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