Combustion synthesized nickel-cobalt catalyst deactivation by coking during ethanol decomposition reaction
Abstract
In this work, we
report the catalytic dehydrogenation of ethanol over porous cobalt oxide and nickel-cobalt
bimetal oxide (NiCoO2). Catalyst deactivation and the nature of carbon
formation on these two catalysts are studied in detail to correlate the active phase
with carbon formation. In-situ FTIR analysis was conducted between 50°C to
400°C on Co3O4 and NiCoO2 catalysts to
understand the reaction mechanism and product selectivity. Addition of Ni
improves the activity for ethanol decomposition by achieving complete ethanol conversion
at 350°C as compared to 420°C for cobalt alone. The crystallinity, morphology
and particle analysis of the spent catalyst after reaction was identified using
XRD, SEM and TEM respectively. The XRD shows a phase change of porous NiCoO2
to NiCo alloy, whereas SEM indicates the presence of fibrous structure on the
surface with 91.7 % of carbon while keeping 1:1 ratio of Ni and Co after the
reaction. The detailed analysis of carbon structure using HRTEM-STEM (Fig. 1)
shows simultaneous growth of carbon nanofibers (CNFs) and multiwalled carbon
nanotubes (MWCNTs) that were favored by larger and smaller crystallites
respectively.
DOI/handle
http://hdl.handle.net/10576/34061Collections
- Chemical Engineering [1174 items ]
- Mechanical & Industrial Engineering [1396 items ]