Catalytic hydrogenation hydroformylation

Catalytic Hydrogenation, Hydroformylation, and Hydroxymethylation of Polybutadiene Synthesis and Characterization... 

Where applicable, the shortsightedness principle can significantly simplify quantitative modeling, especially in networks with coupled parallel steps. Examples are olefin reactions that involve double-bond migration in parallel to conversion to products, as in homogeneous catalytic hydrogenation, hydroformylation, hydro-cyanation, and hydrohalogenation [16]. 

Promising results have been reported by various laboratories since 1990 on catalysis in molten salts, notably for catalytic hydrogenation, hydroformylation, oxidation, alkoxycarbonylation, hydrodimerization/telomerization, oligomerization, and Trost-Tsuji coupling [113]. A continuous-flow application to the linear dimerization of 1-butene on an ionic-liquid nickel catalyst system reached activities with TON > 18000 [116]. 

The reverse reaction (formation of metal alkyls by addition of alkenes to M-H) is the basis of several important catalytic reactions such as alkene hydrogenation, hydroformylation, hydroboration, and isomerization. A good example of decomposition by y3-elimination is the first-order intramolecular reaction ... 

The unsubstituted quinazolidine system 5 was constructed from mesylate 173. The key feature in this synthesis is based on a cyclohydrocarbonylation of the protected 4-amino-l,6-heptadiene 169 catalyzed by Rh(acac)(CO)2-BIPHEPHOS. Formation of the hemiamidal-aldehyde 171 took place by hydroformylation of the two olefin moieties and cyclization. Elimination of water gave 172, which, after treatment with NaBFE, subsequent mesylation to 173, and catalytic hydrogenation, afforded 5 (Scheme 29) <1998TL4599>. 

CH ligands, (2) to initiate homogeneous catalytic reactions such as hydrogenation, hydroformylation, and the water gas shift reaction, and (3) to study the mechanism of thermal reactions by the photochemical preparation of possible intermediates. 

This chapter aims to provide an overview of the current state of the art in homogeneous catalytic hydrogenation of C=0 and C=N bonds. Diastereoselec-tive or enantioselective processes are discussed elsewhere. The chapter is divided into sections detailing the hydrogenation of aldehydes, the hydrogenation of ketones, domino-hydroformylation-reduction, reductive amination, domino hydroformylation-reductive amination, and ester, acid and anhydride hydrogenation. 

From the seminal studies of Sabatier [43] and Adams [44] to the more recent studies of Knowles [45] and Noyori [46], catalytic hydrogenation has been regarded as a method of reduction. The results herein demonstrate the feasibility of transforming catalytic hydrogenation into a powerful and atom-economical method for reductive C-C bond formation. Given the profound socioeconomic impact of al-kene hydroformylation, the development of catalysts for the hydrogen-mediated... 

The water-soluble ligands described above, together with many others, are used to conduct a wide range of catalytic reactions in water. These reactions include hydrogenation, hydroformylation, oxidation, C-C coupling and polymerization reactions [30], Many of these reactions are discussed in detail in Chapters 7-11. 

In Figure 4.2 we have drawn how we can distinguish the two faces of an alkene, or rather the side of attack of a specific atom of the alkene. The arrow on the left approaches the lower carbon of the alkene and when looking from this viewpoint we count the weight of the three substituents the same way as in the CIP rules. We then see the order 1, 2, and 3 counter-clockwise, and we say that the arrow approaches the carbon atom from the si face. For simplicity we call this the si face of the alkene and in most cases this will do. If all four substituents at the alkene are different we can determine the re/si properties of both carbon atoms and these may be different This results in the nomenclature that an alkene may have a re,re and si,si face or re,si and si,re face. Thus, in the latter case one has to indicate to which atom the label is referring. For any enantiospecific, catalytic reaction (hydrogenation, hydroformylation, polymerisation) it is very convenient to use the re and si indicators in the discussion. 

It must be emphasized that the above considerations were made in the absence of reaction. Interfacial mass transfer followed by reaction requires further consideration. The Hatta regimes classify transfer-reaction situations into infinitely slow transport compared to reaction (Hatta category A) to infinitely fast transport compared to reaction (Hatta category H) [42]. In the first case all reaction occurs at the interface and in the second all reaction occurs in the bulk fluid. Homogenous catalytic hydrogenations, carbonylations etc. require consideration of this issue. An extreme example of the severity of mass transport effects on reactivity and selectivity in hydroformylation has been provided by Chaudari [43]. Further general discussions for homogeneous catalysis can be found elsewhere [39[. 

The solubility of gases, e.g. H2, CO and O2, is generally good which makes them attractive solvents for catalytic hydrogenations, carbonylations, hydroformylations, and aerobic oxidations. 

Hydrogenation Hydroformylation 100-300 edible oils hydrogasification hydrocracking desulfurization catalytic cracking naphtha hydroforming coal liquefaction fatty alcohols 1-6-hexanediol 1-4-butanediol hexamethylenedi amine C4 to Cl5 products... 

Hydroformylation to produce aldehydes is the first step in an important industrial route to alcohols. The intermediate aldehydes are reduced to alcohols by catalytic hydrogenation. Large quantities of C4-Cg alcohols are prepared by this sequence ... 

Marko (90) investigated the catalytic hydrogenation of aldehydes and found a similar dependence on carbon monoxide pressure to that found for hydroformylation, in that the reaction had a maximum rate at a low partial CO pressure ( 20 atm at 150° C). Above 32 atm partial pressure of CO the reaction followed the kinetic equation... 

The reaction of alkenes and other unsaturated substances with transition metal hydrido or alkyl complexes is of prime importance in catalytic reactions such as hydrogenation, hydroformylation, and polymerization (see Chapter 22). It is one of the major methods for synthesizing metal-to-carbon bonds. The reverse reaction, the /3-hydride or /3-alkyl transfer-alkene elimination reaction has already been discussed (Section 21-3). 

Unsaturated ligands such as alkenes often undergo insertion into M-H bonds to give alkyls or vinyls (equation 23). This is an important step in catalytic alkene isomerization, hydrogenation, hydroformylation, hydrocyanation, and perhaps also hydrosilation, although in this last case, insertion into the M-Si bond may be preferred. This is simply the reverse of the -elimination reaction discussed above. 

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