Analytical review of the catalytic cracking of methane

Catalytic decomposition of methane (CDM) is a low-carbon hydrogen production process where pure hydrogen and solid carbon are produced. In this study, we investigate catalyst performance in terms of active metals, metal supports, and promoters. These structures are known to strongly influence catalyst activity and stability; where the former is dependent on the size of the formed active metal particles, along with the intensity of their in-teractions with the support; and the latter is contingent on the equilibrium between the rates of decomposition and diffusion of methane. Carbonaceous catalysts exhibit lower activity compared to metallic catalysts, and result in the formation of economically unfavorable amorphous carbon as opposed to the more profitable carbon filaments or nanotubes. Irreducible metal oxides and specific zeolites have shown promising results when used as supports for nickel-based catalysts, especially when coupled with special metallic promoters to either enhance metal-support interactions, or to increase the carbon diffusion rates and enhance the carbon capacity of the catalyst. The metal-support interactions attained within the catalyst should not be too weak as to cause rapid sintering of the active metal, nor too intense as to lead to the formation of spinel structures or solid solutions which are detrimental to catalyst activity. Exploiting the synergic effects of bi-and tri-metallic catalysts is essential in designing a potential catalyst which possesses high activity and stability at moderate operating temperatures.

Automated summary

The study investigates the influence of catalyst performance in methane catalytic decomposition process, focusing on active metals, metal supports, and promoters. The findings suggest that selecting suitable metal supports and promoters can effectively improve catalyst activity and stability.