Catalysts/catalysis metals/metal complexes

Transition metal hydrides play a key role in the catalytic homogeneous isomerization of olefins. The pure hydrides such as HCo(CO)4 can function as the catalyst, or transition metals complexed to stabilizing ligands can function as catalysts the catalysis almost certainly proceeds through hydride intermediates in many cases. 

Most of the catalysts employed in PEM and direct methanol fuel cells, DMFCs, are based on Pt, as discussed above. However, when used as cathode catalysts in DMFCs, Pt containing catalysts can become poisoned by methanol that crosses over from the anode. Thus, considerable effort has been invested in the search for both methanol resistant membranes and cathode catalysts that are tolerant to methanol. Two classes of catalysts have been shown to exhibit oxygen reduction catalysis and methanol resistance, ruthenium chalcogen based catalysts " " and metal macrocycle complexes, such as porphyrins or phthalocyanines. ... 

Advanced Design of Catalyst Surfaces with Metal Complexes for Selective Catalysis... 

This chapter focuses on several recent topics of novel catalyst design with metal complexes on oxide surfaces for selective catalysis, such as stQbene epoxidation, asymmetric BINOL synthesis, shape-selective aUcene hydrogenation and selective benzene-to-phenol synthesis, which have been achieved by novel strategies for the creation of active structures at oxide surfaces such as surface isolation and creation of unsaturated Ru complexes, chiral self-dimerization of supported V complexes, molecular imprinting of supported Rh complexes, and in situ synthesis of Re clusters in zeolite pores (Figure 10.1). 

I 70 Advanced Design of Catalyst Surfaces with Metal Complexes for Selective Catalysis Table 10.6 Performances of Re/zeolite catalysts for direct phenol synthesis at 553 K". 

Mannich reactions give rise to (i-amino carbonyl compounds which are amenable to further synthetic manipulations. Numerous stereoselective variants have been achieved by means of different types of catalysts including both metal complexes and organic molecules. In 2004, the groups of Akiyama and Terada independently selected this transformation as a model reaction for the introduction of a novel chiral motif to asymmetric catalysis [14, 15]. 

At the synthetic level we may expect increased emphasis on enantioselective catalysis usin metal complex catalysts as a key component of the manufacturing process (84). For biocatalysts there will unquestionably continue to be increasing interest in the "custom synthesis" of enzymes engineered for specific functions and conditions. The first example of the "ultimate" enzyme has been reported with the synthesis of the all-D form of HIV-1 protease (85-87). This enzyme exhibits a chiral specificity opposite to that of the naturally occurring L form and it may be generally predicted that enantiomeric proteins will exhibit reciprocal chiral specificity in all aspects of their interactions. These reciprocal chiral... 

Solid-Supported Surface Catalysis by Metal Complexes. Hong et al. (1987a, b, in press) have prepared a variety of hybrid catalysts between Co(II) phthalocyanine complexes and the surfaces of silica gel, polystyrene-divinylben-zene, and Ti02 and tested these hybrids for catalytic activity with respect to the autoxidation of hydrogen sulfide, sulfur dioxide, 2-mercaptoethanol, cysteine, and hydrazine ... 

This is an important area with many available methods. We shall look first at organic catalysis and then change to catalysis by metal complexes. The same type of intermediate 117 used for conjugate addition is clearly also suitable for Diels-Alder reactions with the same proviso it must be more reactive then the a,(5-unsaturated carbonyl compound as that too can do Diels-Alder reactions. And of course the first formed product 118 must hydrolyse rapidly to release the catalyst 102. 

The synthesis of the chiral copper catalyst is very easy to reproduce. The complex catalyses the asymmetric alkylation of enolates of a range of amino acids, thus allowing the synthesis of enantiomeric ally enriched a,a disubstituted amino acids with up to 92% ee. The procedure combines the synthetic simplicity of the Phase Transfer Catalyst (PTC) approach, with the advantages of catalysis by metal complexes. The chemistry is compatible with the use of methyl ester substrates, thus avoiding the use of iso-propyl or ferf-butyl esters which are needed for cinchona-alkaloid catalyzed reactions[4], where the steric bulk of the ester is important for efficient asymmetric induction. Another advantage compared with cinchona-alkaloid systems is that copper(II)(chsalen) catalyses the alkylation of substrates derived from a range of amino acids, not just glycine and alanine (Table 2.4). 

Many catalysts are metals, metal oxides or other simple salts, or metal complexes. For example, formation of platinum(IV) complexes involving ligand substitution is an extremely slow process, due to the kinetic inertness of this oxidation state. However, the addition of small amounts of a platinum(II) complex to the reaction mixture leads to excellent catalysis of the reaction, assigned to mixed oxidation state bridged intermediates that promote ligand transfer. 

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