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Selective catalysis

Brey W S 1983 Applications of magnetic resonance in catalytic research Heterogeneous Catalysis Selected American Stories ed B FI Davis and W P Flettinger Jr (Washington American Chemical Society)... [Pg.1799]

Gaines, G.L. and Wise, G. (1983) in Heterogeneous Catalysis Selected American Histories. ACS Symposium Series 222 (American Chemical Society, Washington, DC) p. 13. [Pg.16]

Haensel, V. (1983). The Development of the Platforming Process—.Some Personal and Catalytic Recollections. In Heterogeneous Catalysis Selected American Histones, eds. B. H. Davis and W. P. Hettinger. Aiiiericaii Clieiiiical Society. Symposium Series No. 222. Washington, DC American Chemical Society. [Pg.680]

Y. Goldberg, Phase Transfer Catalysis. Selected Problems and Applications, Gordon and Breach, Yverdon, 1989... [Pg.162]

Goldberg, Y. (1989) Phase Transfer Catalysis Selected Problems and Applications., Gordon and Breach Science Publishers, Yverdon, Switzerland. [Pg.359]

RNA catalysis and in vitro selection are ever increasing in scope, and the method presented in Section 8.3.6.1 is by no means the only alternative for separating reacted/active- catalyst complexes. Most research groups have used this type of partitioning procedure, based on some type of biotin-product capture by streptaviclin. Other partitioning methods are possible and this step in the overall RNA catalysis selection cycle is where many new innovations need to occur to advance the field. [Pg.107]

Centi, G. and Perathoner, S. Encyclopedia of Catalysis, Selective Oxidation — Section E (ed. I.T. Horvath), John Wiley Sons, Inc., New York... [Pg.74]

Davis, B., and Hettinger, W., Jr., eds. (1983). Heterogeneous Catalysis Selected American Histories. Am. Chem. Soc., Washington DC. Gates, B. C. (1991). Catalytic Chemistry (The Wiley Series in Chemical Engineering), Wiley, New York. [Pg.102]

NHA oxime or proton donation from protonated N to the heme species are suggested as likely mechanistic pathways [106], Regardless of the final mechanism, the L-Arg and NHA-bound structures of NOS imply that NOS catalysis selects between two different reductive activations of dioxygen. [Pg.1740]

Table 2.14 Example of industrial processes or processes under development based on asymmetric catalysis selected chiral ligands are shown at the end of the table. Source adapted from Blaser and Scmidt [312]. Table 2.14 Example of industrial processes or processes under development based on asymmetric catalysis selected chiral ligands are shown at the end of the table. Source adapted from Blaser and Scmidt [312].
Key Words Ethylene oxide, Ethylene, Epoxidation, Silver, Cl promotion, Cs promotion. Promotion, Selectivity, Oxametallacycle, Adsorption, Desorption, Chemisorption, Activation energy, Ag-O bond. Reaction mechanism, Oxidation, Cyclisation, Heterogeneous catalysis, Selective oxidation, Eletrophilic oxygen. Nucleophilic oxygen. Subsurface O atoms, Ag/a-A Oj catalyst. 2008 Elsevier B.V. [Pg.234]

Scheme 16 Dehydrative glycosylations via Lewis acid catalysis Selected coupling partners [55-60],... Scheme 16 Dehydrative glycosylations via Lewis acid catalysis Selected coupling partners [55-60],...
Yadav, G. D., and P. H. Mehta, Theoretical and Experimental Analysis of Capsule Membrane Phase Transfer Catalysis Selective Alkaline Hydrolysis of Benzyl Chloride to Benzyl Alcohol, Catal. Lett., 21, 391 (1993). [Pg.35]

Capsule membrane phase transfer catalysis selective alkaline hydrolysis and oxidation of benzyl chloride to benzyl alcohol and benzaldehyde... [Pg.503]

See other pages where Selective catalysis is mentioned: [Pg.13]    [Pg.65]    [Pg.515]    [Pg.2]    [Pg.280]    [Pg.568]    [Pg.66]    [Pg.15]    [Pg.240]    [Pg.521]    [Pg.750]    [Pg.577]    [Pg.340]    [Pg.331]    [Pg.548]    [Pg.1278]    [Pg.231]    [Pg.162]    [Pg.6]    [Pg.134]    [Pg.66]    [Pg.213]   
See also in sourсe #XX -- [ Pg.163 ]

See also in sourсe #XX -- [ Pg.352 ]



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Active Ensemble Structures for Selective Oxidation Catalyses at Surfaces

Advanced Design of Catalyst Surfaces with Metal Complexes for Selective Catalysis

Alkanes, selective oxidation, cobalt catalysis

Antibody catalysis, selective

Asymmetric homogeneous catalysis selectivity

Catalysis selective catalysts

Catalysis selective epoxidation

Catalysis selective hydrogenation

Catalysis selective oxidation

Catalysis selective photocatalysis

Catalysis selectivity research

Catalysis shape selectivity

Catalysis site-selectivity

Catalysis, homogeneous selectivity

Catalysis/catalysts shape-selective

Enzymatic catalysis selectivity

Fischer-Tropsch catalysis product selectivities

Geometrical Constraints Shape-selective Catalysis

Heterogeneous catalysis selective catalysts

Heterogeneous catalysis selectivity

Heterogenous catalysis selective hydrogenation

Heterogenous catalysis selective oxidation

Lewis acids highly selective catalysis

Managing Carbon Losses for Selective Oxidation Catalysis

Metal-oxide catalysis selected applications

Molecular shape-selectivity, zeolite catalysis

Molybdate selective oxidation catalysis

Product shape selectivity , zeolite catalysis

Product-selective catalysis

Reactant shape selectivity , zeolite catalysis

Reactant-selective catalysis

Restricted transition-state selectivity catalysis

SELECTIVITY IN CATALYSIS

Selected Examples for Dendritic Polymer-supported Catalysis

Selectivity Lewis base-promoted catalysis

Selectivity catalysis

Selectivity cobalt catalysis

Selectivity in Oxidation Catalysis

Selectivity in homogeneous catalysis

Shape selective catalysi

Shape selective catalysis, zeolites

Shape-selective catalysis

Shape-selective catalysis development

Shape-selective catalysis with zeolites

Transition-state selective catalysis

Transition-state selectivity , zeolite catalysis

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