Blue hydrogen and carbon nanotube production via direct catalytic decomposition of methane in fluidized bed reactor: Capture and extraction of carbon in the form of CNTs

The current study reports a regenerative approach for producing blue hydrogen (COx-free) and carbon nanotubes (CNTs) from natural gas (methane). The multi-metallic nickel-based copper and zinc promoted catalyst with an optimal composition (60%Ni-5%Cu-5%Zn/Al2O3) was synthesized in the laboratory and used for the pyrolysis of methane in a fluidized bed reactor under bubbling conditions. Fluidized bed reactor hydrodynamics and CNT extraction were well-thought-out while designing the catalyst. The separation of the CNTs and partial regeneration of the spent catalyst was performed using the ultrasonication technique. The regeneration ability of the catalyst was examined by performing multiple reaction-regeneration cycles. The regenerated catalyst regained its full activity, and >90% methane conversion was achieved with high-quality CNTs (o.d 60-80 nm, length 5 mu m). State-of-the-art characterization tools like 3D-Raman mapping, high-resolution electron microscopy, EDX mapping were utilized to analyze CNTs. 3D-Raman map consists of 29,200 spectra ensured the uniformity and purity of grown CNTs.

Automated summary

This study presents a regenerative approach for producing blue hydrogen and carbon nanotubes from natural gas, utilizing a synthesized catalyst in a fluidized bed reactor. The catalyst design considered fluidized bed reactor hydrodynamics and CNT extraction, with the catalyst successfully regenerated using ultrasonication. Advanced characterization tools such as 3D-Raman mapping were used to analyze and confirm the quality of the CNTs produced.