The hydrogen production through the decomposition of methane into hydrogen and carbon on Ni supported catalysts followed by catalyst regeneration in oxidative atmosphere was evaluated. Typical temperature programmed catalytic reaction (TPCR) results revealed that the nature of the carrier slightly affects the onset temperature of CH4 decomposition, while catalytic performance and regeneration capacity in O2 or CO2 streams depend on dispersion and morphology of the active phase. The structure-sensitive character of methane decomposition reaction has been confirmed. TEM analyses of the spent catalysts revealed that both filamentous and encapsulating carbon species were formed under isothermal conditions at 823 K, the last being responsible for catalyst deactivation.
A basic assessment of the reactivity of Ni catalysts in the decomposition of methane for the production of COx-free hydrogen for fuel cells application
Bonura G;Di Blasi O;Spadaro L;Arena F;Frusteri F
2006
Abstract
The hydrogen production through the decomposition of methane into hydrogen and carbon on Ni supported catalysts followed by catalyst regeneration in oxidative atmosphere was evaluated. Typical temperature programmed catalytic reaction (TPCR) results revealed that the nature of the carrier slightly affects the onset temperature of CH4 decomposition, while catalytic performance and regeneration capacity in O2 or CO2 streams depend on dispersion and morphology of the active phase. The structure-sensitive character of methane decomposition reaction has been confirmed. TEM analyses of the spent catalysts revealed that both filamentous and encapsulating carbon species were formed under isothermal conditions at 823 K, the last being responsible for catalyst deactivation.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
