Litcius/Paper detail

Catalyst Deactivation by Carbon Deposition: The Remarkable Case of Nickel Confined by Atomic Layer Deposition

Shaik Afzal, Anuj Prakash, Patrick Littlewood, Hanif A. Choudhury, Zafar Khan Ghouri, Said Mansour, Dingdi Wang, Tobin J. Marks, Eric Weitz, Peter C. Stair, Nimir O. Elbashir

2021ChemCatChem18 citationsDOI

Abstract

Abstract In hydrocarbon reforming processes, coke formation on the catalyst usually reduces reaction rates. We show that when subjected to thermal treatment, a commercial nickel catalyst, overcoated with alumina, ALD exhibited both higher activity per g Ni and higher carbon formation rates than an uncoated catalyst. During the temperature‐programmed reaction in a CH 4 +CO 2 atmosphere, the uncoated catalyst deactivated rapidly from carbon buildup, but the overcoated catalyst displayed an increase in catalytic activity per g Ni, despite generating two times the surface carbon. The unexpected phenomenon was investigated via TEM/EDS, TGA/DSC, SEM, XRD and Raman spectroscopy. We hypothesize that this may be due to (a) formation of a thicker than expected ‘quasi‐ALD’ overcoat of amorphous alumina, (b) crystallization of ALD overcoat into nanofibers that act as secondary supports for migrating Ni, and (c) the ability of ALD overcoat to isolate carbon as carbon nano‐onions (CNOs).

Topics & Concepts

CatalysisAtomic layer depositionNickelCarbon fibersChemical engineeringAmorphous carbonRaman spectroscopyDeposition (geology)Materials scienceCokeHydrocarbonCrystallizationLayer (electronics)ChemistryInorganic chemistryAmorphous solidNanotechnologyOrganic chemistryMetallurgyComposite materialComposite numberSedimentOpticsEngineeringBiologyPhysicsPaleontologyCatalytic Processes in Materials ScienceGraphene research and applicationsCarbon Nanotubes in Composites