Effect of Nickel Precursor on the Catalytic Performance of Graphene Aerogel-Supported Nickel Nanoparticles for the Production of COx-free Hydrogen by Ammonia Decomposition

Graphene aerogel (GA), a promising porous material with high specific surface area and electrical conductivity, is utilized to disperse nickel nanoparticles to reach high catalytic activity in COx-free hydrogen production from ammonia. Ni(NO3)(2)center dot 6H(2)O and Ni (II) acetylacetonate (Ni(acac)(2)) were considered as metal precursors and the pH of the impregnation solution was varied to investigate the effects on the catalytic properties of the GA-supported nickel catalysts. Data showed that the best dispersion and homogeneity, as well as the catalytic performance, is achieved with Ni(acac)(2). An average Ni nanoparticle size of 13.6 +/- 4.3 nm was obtained on the GA-supported catalyst prepared by using Ni(acac)(2) dissolved in an impregnation solution with a pH of 10.2. This catalyst with a Ni loading of 11.1 wt% provided an ammonia conversion of 70.2% at a space velocity of 30 000 mL NH3 g(cat)(-1) h(-1) and 600 degrees C corresponding to a hydrogen production rate of 21.5 mmol H-2 g(cat)(-1) min(-1). Data illustrated that the difference between the point of zero charge of the support and the pH of the impregnation solution set by the type of the Ni precursor is a major parameter controlling the metal dispersion and the consequent catalytic activity.

Automated summary

Graphene aerogel is utilized to disperse nickel nanoparticles for high catalytic activity in COx-free hydrogen production from ammonia. Using Ni(acac)(2) as the metal precursor in an impregnation solution with a pH of 10.2, the catalyst shows the best dispersion and catalytic performance.