Sintered Ni metal as a matrix of robust self-supporting electrode for ultra-stable hydrogen evolution

For the self-supporting catalysts of Hydrogen evolution reaction (HER), the rational design and fabrication of substrate with porous structure and sufficient mechanical strength are critical to promoting the industrial HER application. In this work, a novel porous sintered Ni metal as the matrix for supporting catalysts was successfully prepared by powder metallurgy, and a self-supporting electrode for HER was fabricated via a simple sulfurization process on this sintered Ni metal matrix. For instance, MoS2/Ni3S2 nanorods (NRs) were vertically grown on the as-sintered porous Ni matrix, and the morphology of the sintered Ni matrix significantly affected the growth of MoS2/Ni3S2 NRs. The NRs@Sintered Ni electrode shows a low overpotential of eta 10 = 56 mV and Tafel slope of 82 mV dec. Compared with NRs@Ni foam, the NRs@Sintered Ni exhibits superior stability, where no exfoliation and cracks are observed on the surface of the electrode after 5000 CV cycles. Ultra-high stability and longterm durability are obtained over 100 h even at high potentials of 200 and 300 mV. Moreover, the tensile strength of the as-obtained electrode based on the sintered Ni manifests nearly 260 times higher than that of NRs@Ni foam, evidencing an excellent mechanical property. This work provides an idea for the preparation of self-supporting metal-based catalytic electrodes in large-scale hydrogen production.

Automated summary

In this study, a novel porous sintered Ni metal matrix was successfully prepared for supporting catalysts, and a self-supporting electrode for HER was fabricated via a simple sulfurization process. The electrode showed superior stability and long-term durability, along with excellent mechanical properties, demonstrating a new idea for the preparation of self-supporting metal-based catalytic electrodes for large-scale hydrogen production.