Heterogeneous metal-catalyzed

The WGSR is normally practised as a heterogeneously metal-catalyzed reaction Fe is the most commonly used catalyst. However other metals are also active, for example the homogeneous Rh/H catalyst in the Monsanto acetic acid process (Section 4.2.4) concurrently catalyzes the WGSR via a Rh(I)/ Rh(III) cycle (Equations 8 and 9),... 

Two types of metal-catalyzed procedures are now available for these reactions. Extensive studies have been made with heterogeneous systems which utilize a wide range of Group VIII transition metals. Recently, homogeneous metal-catalyzed systems have also been discovered.58 In this section, heterogeneous metal-catalyzed exchange only will be discussed and current homogeneous developments will be treated in the final section of this chapter. 

Compound classes labeled by heterogeneous metal-catalyzed tritium exchange from water include amino acids, peptides and proteins, sugars, polycyclic aromatic hydrocarbons, purines, pyrimidines and nucleosides, alkyl-substituted aromatics, alicyclic compounds and steroids, A-heterocycles and anilines and some O- and 5-heterocycles. The method is firmly fixed in the repertoire of methods of the commercial custom labeling industry. 

The metal catalyzed production of polyolefins such as high density polyethylene (HDPE), linear low density polyethylene (LLDPE) and polypropylene (PP) has grown into an enormous industry. Heterogeneous transition metal catalysts are used for the vast majority of PE and all of the PP production. These catalysts fall generally within two broad classes. Most commercial PP is isotactic and is produced with a catalyst based on a combination of titanium chloride and alkylaluminum chlorides. HDPE and LLDPE are produced with either a titanium catalyst or one based on chromium supported on silica. Most commercial titanium-based PE catalysts are supported on MgCl2. 

Combinatorial approach to unsymmetrically tiered macromolecules [214] is a brand new area of research which would allow dendrimerization of materials (e. g., glass, classical polymers, fibers) and thus enable fine tuning of macromole-cular properties. For example, treatment of an amine terminated dendrimer with a mixture of complementary, isocyanate-based monomers [215, 216] affords a heterogeneous surfaced dendrimer. Selective transformation of the surface nitrile moieties via metal-catalyzed reduction to obtain a new polyamine dendrimer allows further combinatorial-based elaboration as illustrated in Fig. 42. 

There has been considerable recent research interest in the activation of carbon monoxide en route to more complex organic molecules. Among the various reactions that have been investigated and/or newly discovered, the transition metal catalyzed reduction of CO to hydrocarbons (Fischer-Tropsch synthesis) has enjoyed particular attention (l- ). Whereas most of the successful efforts in this area have been directed toward the development of heterogeneous catalysts, there are relatively few homogeneous systems. Among these, two are based on clusters (10,11) and others are stoichiometric in metal (12-17). In this report we detail the synthesis and catalytic chemistry of polystyrene ( ) supported... 

If the catalyst is in the same phase as the reactant (e.g., dissolved metals catalyzing transformation of dissolved organic substances), the catalysis is called homogeneous. When the catalytic process is determined by a catalyst in a different phase than the reactant (e.g., solid metal oxides catalyzing transformation of dissolved organic or inorganic substances), the catalysis is called heterogeneous. In this case, the catalyzed reaction steps occur very close to the solid surface the reactions may be between the molecules adsorbed on the catalyst surface or may involve the top-most atomic layer of the catalyst. 

Transition metal catalyzed reactions are becoming commonplace in synthetic chemistry. Heterogeneous or homogeneous catalysts containing valuable metals such as palladium, platinum, rhodium and ruthenium are frequently used in the manufacture of active pharmaceutical ingredients (API).[1] The use of such catalysts can lead to metal contamination of the product. The amount of precious... 

The use of alkyl hydroperoxides in the metal-catalyzed epoxidation of alkenes is their most important synthetic application. High-valence d° metals such as Mo(VI), W(VI), V(V), and Ti(IV) are the most effective catalysts 24 245,278,279,285,286 Used as soluble complexes or as heterogenized supported catalysts, they can give epoxides in near-quantitative yields. 

The formation of benzene (or substituted benzene derivatives) is a common transformation catalyzed by numerous homogeneous and heterogeneous metal catalysts, mainly Co, Rh, Pd, and Ni.63-69 Even highly crowded molecules, such as hexaisopropylbenzene, could be synthesized in the presence of metal carbonyls such as [Co(CO)4]2.70 A very simple catalyst system, Me3SiCl and Pd on carbon in refluxing tetrahydrofuran, has been shown to transform symmetrical alkynes into hexaalkylbenzenes in excellent yield.71... 

Recently, heterogeneous catalytic systems were described41 that employ molecular oxygen for the liquid phase oxidative cleavage of vicinal diols. Although the catalysts appear to be mixed metal oxides rather than supported metals the method resembles closely the noble metal-catalyzed oxidations described above, hence their inclusion in this section. 

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