Electrospun carbon nanofibers with in-situ encapsulated Ni nanoparticles as catalyst for enhanced hydrogen storage of MgH2.

Transition-metals have emerged as promising catalyst candidates for improving the hydrogen storage properties of MgH2. However, the preparation of uniformly dispersed and extra-fine transition-metals catalysts with high catalytic activity still remains a challenge. In this paper, an electrospinning-based reduction approach is presented to generate nanostructured nickel catalyst, which is protected from irreversible fusion and aggregation in subsequent high-temperature pyrolysis, in carbon nanofibers (Ni@C) in situ. The obtained Ni@C reveals remarkable catalytic effect on improving the hydrogen storage properties of MgH2. For example, the MgH2-10 wt%Ni@C composite delivers dehydrogenation capacities of 5.79 wt% and 6.12 wt% at 280 °C and 300 °C, respectively, whereas the as-milled MgH2 hardly decomposes at the same temperature. By Arrhenius plots, the calculated Ea of the dehydrogenation of MgH2-10 wt%Ni@C is 93.08 kJ mol−1, which is 94.33 kJ mol−1 lower than that of the as-milled MgH2. Furthermore, the microstructure of Ni@C is remained during the re/dehydrogenation process and the Ni nanoparticles are still distributed homogeneously in the composite, accounting for the excellent cycling performance. This study could render combinations of ultrafine metal nanoparticles with carbon accessible, thereby, extending opportunities in catalytic applications for hydrogen storage. The homogeneously distributed Ni with refined particle size in carbon nanofibers has been synthesized successfully. A certain proportion of Ni@C and commercial MgH 2 were mechanically mixed by high-energy ball milling and the Ni@C were uniformly dispersed on the surface of MgH 2 , which enhanced the interface interaction and reduced the apparent activation energy of the dehydrogenation of MgH 2 -10 wt % Ni@C. Image 1 • Ni nanoparticles in-situ encapsulated in carbon nanofibers has been synthesized successfully by electrospinning technique. • The Ni@C catalyst was uniformly dispersed on the surface of MgH 2 by high-energy ball milling. • The MgH 2 -10 wt %Ni@C delivers a hydrogen release of 5.91 wt% in 500 s at 325 °C. • The hydrogen storage capacity of the MgH 2 -10 wt %Ni@C composite can be maintained without degradation after 20 cycles. [ABSTRACT FROM AUTHOR]