Fischer-Tropsch synthesis: Support and cobalt cluster size effects on kinetics over Co/Al sub(2)O sub(3) and Co/SiO sub(2) catalysts

The influence of support type and cobalt cluster size (i.e., with average diameters falling within the range of 8-40 nm) on the kinetics of Fischer-Tropsch synthesis (FT) were investigated by kinetic tests employing a CSTR and two Co/ gamma -Al sub(2)O sub(3) catalysts having different average pore...

Full description

Saved in:
Bibliographic Details
Published in:Fuel (Guildford) 2011-02, Vol.90 (2), p.756-765
Main Authors: Ma, Wenping, Jacobs, Gary, Sparks, Dennis E, Gnanamani, Muthu K, Pendyala, Venkat Ramana Rao, Yen, Chia H, Klettlinger, Jennifer LS, Tomsik, Thomas M, Davis, Burtron H
Format: Article
Language:English
Subjects:
Catalysis
Catalysts
Clusters
Cobalt
Mathematical models
Porosity
Reaction kinetics
Silicon dioxide
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The influence of support type and cobalt cluster size (i.e., with average diameters falling within the range of 8-40 nm) on the kinetics of Fischer-Tropsch synthesis (FT) were investigated by kinetic tests employing a CSTR and two Co/ gamma -Al sub(2)O sub(3) catalysts having different average pore sizes, and two Co/SiO sub(2) catalysts prepared on the same support but having different loadings. A kinetic model [inline image] that contains a water effect constant "m" was used to fit the experimental data obtained with all four catalysts. Kinetic parameters suggest that both support type and average Co particle size impact FT behavior. Cobalt cluster size influenced kinetic parameters such as reaction order, rate constant, and the water effect parameter. In the cluster size range studied, decreasing the average Co cluster diameter by about 30% led to an increase in the intrinsic reaction rate constant k, defined on a per g of catalyst basis, by 62-102% for the gamma -Al sub(2)O sub(3) and SiO sub(2)-supported cobalt catalysts. This increase was due to the higher active Co super(0) surface site density as measured by hydrogen chemisorption. Moreover, less inhibition by adsorbed CO and greater H sub(2) dissociation on catalysts having smaller Co particles was suggested by the higher a and lower b values obtained for the measured reaction orders. Interestingly, irrespective of support type, the catalysts having smaller average Co particles were more sensitive to water. Comparing the catalysts having strong interactions between cobalt and support (Co/Al sub(2)O sub(3)) to the ones with weak interactions (Co/SiO sub(2)), the water effect parameters were found to be positive (indicating a negative influence on CO conversion) and negative (denoting a positive effect on CO conversion), respectively. No clear trend was observed for b values among the different supports, but greater a and a/b values were observed for both Al sub(2)O sub(3)-supported Co catalysts, implying greater inhibition of the FT rate by strongly adsorbed CO on Co/Al sub(2)O sub(3) relative to Co/SiO sub(2). For both supports, the order on P sub(CO) was always found to be negative (i.e., suggesting an inhibiting effect) and positive for P sub(Hd2) for all four catalysts. The order of the reaction on P sub(Hd2) was close to 0.5, suggesting that dissociated H sub(2) is likely involved in the catalytic cycle. Finally, in the limited range of average pore diameters studied (13.5 and 18.2 nm), the ave
ISSN:0016-2361
DOI:10.1016/j.fuel.2010.10.029