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Fischer-Tropsch synthesis effects

Li, J.L., Jacobs, G., Das, T.K., and Davis, B.H. 2002. Fischer-Tropsch synthesis Effect of water on the catalytic properties of a ruthenium promoted Co/Ti02 catalyst. Appl. Catal. 233 255-62. [Pg.46]

T. K. Das, W. Conner, G. Jacobs, J. Li, K. Chaudhari and B. H. Davis, Fischer-Tropsch synthesis Effect of water on activity and selectivity for a cobalt catalyst, Stud. Surf. Sci. Catal., 2004, 147, 331-336. [Pg.28]

J. Li, X. Zhan, Y. Zhang, G. Jacobs, T. Das and B. H. Davis, Fischer-Tropsch synthesis effect of water on the deactivation of Pt promoted Co/Al203 catalysts, Appl. Catal. A, 2002, 228, 203-212. [Pg.28]

Abbaslou RMM, Tavassoli A, Soltan J, Dalai AK. Iron catalysts supported on carbon nanombes for Fischer—Tropsch synthesis effect of catalytic site position. Appl Catal A 2009 367 47-52. [Pg.152]

Gnanamani, M. K. Shafer, W. D. Sparks, D. E. Davis, B. H. Fischer-Tropsch Synthesis Effect of COj Containing Syngas over Pt Promoted Co/y-Al Oj and K-Pro-motedFe Catalysts. Catal. Comm. 2011,12, 936-939. [Pg.204]

Bambal, A.S., et al., 2014. Poisoning of a silica-supported cobalt catalyst due to presence of suUiir impurities in syngas during Fischer-Tropsch synthesis effects of chelating agent. Industrial Engineering Chemistry Research 53 (14), 5846—5857. [Pg.352]

Alkali promoters are often used for altering the catalytic activity and selectivity in Fischer-Tropsch synthesis and the water-gas shift reaction, where C02 adsorption plays a significant role. Numerous studies have investigated the effect of alkalis on C02 adsorption and dissociation on Cu, Fe, Rh, Pd, A1 and Ag6,52 As expected, C02 always behaves as an electron acceptor. [Pg.42]

The formation of relatively stable vesicles did not require the presence of pure compounds mixtures of components could also have done the job. However, whether the concentrations of the compounds isolated from the Murchison meteorite would have been sufficient for the formation of prebiotic protocells or vesicles is unclear, even if concentration effects are assumed. Sequences in which the technical Fischer-Tropsch synthesis is the role model have been proposed as possible sources of amphiphilic building blocks. [Pg.268]

Jacobs G., Das T.K., Zhang Y., Li J., Racoillet G., Davis B.H. 2002. Fischer-Tropsch synthesis Support, loading and promoter effects on the reducibility of cobalt catalysts. Appl. Catal. A Gen. 233 263-81. [Pg.14]

Zhang Y., Hanayama K., and Tsubaki N. 2006. The surface modification effects of silica support by organic solvents for Fischer-Tropsch synthesis catalysts. Catal. Commun. 7 251-54. [Pg.15]

Bezemer, G. L., Radstake, P. B., Falke, U., Oosterbeek, H., Kuipers, H. P. C. E., van Dillen, A., and de Jong, K. P. 2006. Investigation of promoter effects of manganese oxide on carbon nanofiber-supported cobalt catalysts for Fischer-Tropsch synthesis. Journal of Catalysis 237 152-61. [Pg.29]

Huang, X. W., Elbashir N. O., and Roberts, C. B. 2004. Supercritical solvent effects on hydrocarbon product distributions from Fischer-Tropsch synthesis over an alumina-supported cobalt catalyst. Industrial Engineering Chemistry Research 43 6369-81. [Pg.29]

Effect of a Novel Nitric Oxide Calcination on the Catalytic Behavior of Silica-Supported Cobalt Catalysts during Fischer-Tropsch Synthesis, and Impact on Performance Parameters... [Pg.31]

Claeys, M., and van Steen, E. 2002. On the effect of water during Fischer-Tropsch synthesis with a ruthenium catalyst. Catal. Today 71 419-27. [Pg.46]

Krishnamoorthy, S., Tu, M., Ojeda, M. P., Pinna, D., and Iglesia, E. 2002. An investigation of the effects of water on rate and selectivity for the Fischer-Tropsch synthesis on cobalt-based catalysts. J. Catal. 211 422-33. [Pg.46]

Bertole, C.J., Mims, C.A., and Kiss, G. 2002. The effect of water on the cobalt-catalyzed Fischer-Tropsch synthesis. J. Catal. 210 84—96. [Pg.47]

Tihay, F., Pourroy, G., Richard-Plouet, M., Roger, A. C., and Kiennemann, A. 2001. Effect of Fischer-Tropsch synthesis on the micro structure of Fe-Co-based metal/spi-nel composite materials. Appl. Catal. A 206 29 -2. [Pg.79]

Nurunnabi, M., Murata, K., Okabe, K., Inaba, M., and Takahara, I. 2007. Effect of Mn addition on activity and resistance to catalyst deactivation for Fischer-Tropsch synthesis over Ru/A1203 and Ru/Si02 catalysts. Catal. Commun. 8 1531-37. [Pg.93]

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See also in sourсe #XX -- [ Pg.203 ]



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