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Unveiling the role of Metal–Support interactions in Ni catalysts for CO2-Free hydrogen and carbon nanotube production via methane pyrolysis

So Yeong Yang, Ji Su Yun, Hye Won Park, Jae‐Hoon Kim, Nodira Saidova, Hyeongeon Lee, Kwangjin An, Ji Sun Im, Soo Hong Lee

2025International Journal of Hydrogen Energy7 citationsDOIOpen Access PDF

Abstract

As the demand for hydrogen (H 2 ) production rises alongside the global push for net-zero CO 2 emissions, methane pyrolysis (MP) has emerged as a promising technology for CO 2 -free H 2 generation. Ni-based catalysts are widely studied for MP due to their ability to activate CH 4 in the low reaction temperature, but rapid deactivation caused by carbon by-products remains a challenge. In this study, we investigated the role of metal-support interactions on the catalytic performance and carbon nanotube (CNT) production in MP. A series of NiO-supported alumina catalysts were synthesized via a one-step solution combustion synthesis method with controllable NiO nanoparticle (NP) sizes and loading levels. The optimized catalyst exhibited an activation energy of 54.2 kJ/mol and remained active for up to 9 h. All catalysts in the series generated high quality CNTs as byproducts of MP, exhibiting controllable diameters and varying degrees of graphitization. Comprehensive analysis indicated no direct correlation between carbon yield and structural properties of catalysts such as NP size, surface area, dispersion or oxidation states. In contrast, hydrogen temperature-programmed reduction measurements revealed that the carbon yield was closely linked to the presence of β 2 -type NiO species associated with an Al-rich mixed oxide phase. Catalysts with higher amounts of β 2 -type NiO showed increased carbon production, likely driven by improved carbon diffusion at the Ni–Al 2 O 3 interface. These results emphasize the importance of fine-tuning metal-support interactions to achieve optimal catalytic performance, enabling efficient H 2 and CNT generation simultaneously during MP. • Solution combustion synthesis of Ni-based catalysts was developed for hydrogen production through methane pyrolysis. • β 2 -type NiO species in Al-rich domains govern both catalytic stability and carbon nanotube formation. • The optimal catalyst achieves 70 % CH 4 conversion, remains active for 9 h, and co-produces high-quality CNTs. • Tailored metal–support interactions boost hydrogen yield and valuable carbon byproducts.

Topics & Concepts

Hydrogen productionCatalysisMethanePyrolysisCarbon nanotubeHydrogenMaterials scienceMetalNickelChemical engineeringCarbon fibersNanotechnologyInorganic chemistryChemistryOrganic chemistryMetallurgyComposite numberEngineeringComposite materialCatalysts for Methane ReformingCatalytic Processes in Materials ScienceCatalysis and Oxidation Reactions