Rhodium complexes catalyzed

Rhodium complexes catalyze the oxidative coupling of benzene with ethene to produce styrene directly.45,45a,45b Using Rh(ppy)2(OAc) (ppyH = 2-phenylpyridine), the reaction of benzene with ethene in the presence of 02 and Cu(OAc)2 in benzene and acetic acid at 180 °C gives styrene and vinyl acetate in 77% and 23% selectivities, respectively. 

Rhodium complexes catalyze 1,2-addition of main group metal compounds to aldimines as well. Table 5 summarizes the reported methods. Electron-withdrawing substituents such as sulfonyl and acyl groups on the imino nitrogen atom are important to obtain sufficiently high reactivity. Asymmetric synthesis (diastereoselective and enantioselective) has also been accomplished. 

Rhodium complexes catalyze hydrosilylation-cyclization of 1,6-allenynes in the presence of (MeO SiH.77 To avoid complex product distributions, the use of substrates possessing fully substituted alkyne and allene termini is imperative. As shown in the cyclization of 1,6-allenyne 62a, the regiochemistry of silane incorporation differs from that observed in the rhodium-catalyzed hydrosilylation-cyclization of 1,6-enynes (see Section 10.10.2.3.2). For allenyne substrates, allene silylation occurs in preference to alkyne silylation (Scheme 40). 

Aizenberg and Milstein [78] have found rhodium complex-catalyzed reactions between polyfluorobenzenes and hydrosilanes which resulted in the substitution of fluorine atoms by hydrogen and were both chemoselective and regioselective (Eq. (6) ... 

The enhanced synthetic potential of rhodium-complex-catalyzed enantioselective hydrogenation provided by these advances in ligand design has led to renewed interest in the reaction mechanism, and here we highlight four recent topics (i) the extended base of reactive intermediates (ii) an improved quadrant model for ligand-substrate interactions (iii) computational approaches to mechanism and (iv) (bis)-monophosphine rhodium complexes in enantioselective hydrogenation. These are discussed in turn. 

Status of the Computational Study of Rhodium-Complex-Catalyzed Enantioselective Hydrogenation... 

Fig. 31.14 The present state of knowledge on rhodium-complex-catalyzed enantioselective hydrogenation. The H2 addition stage in the main cycle is predicted to be two-step in DFT calculations whether that or migratory insertion is turnover-limiting remains debatable.

A similar phenomenon was observed in a homogeneous rhodium complex catalyzed hydrogenation (equation 56)6. 

When substituted silanes are used instead of hydrogen, the process is referred to as silylformylation or silylcarbonylation. Only rhodium complexes catalyze the transformation of unsaturated compounds to silylaldehydes via the silylformylation reaction. Iridium complexes also are able to catalyze the simultaneous incorporation of substituted silanes and CO into unsaturated compounds, although during the reaction other types of product are formed. In the presence of [ IrCl(C03) ] and [Ir4(CO)i2]) the alkenes react with trisubstituted silanes and CO to give enol silyl ethers of acyl silanes [58] according to Scheme 14.10. 

A cationic rhodium complex-catalyzed codimerization of 1,3-dienes with alkynes gives the corresponding cyclohexadienes in good yields with high regioselectively, as exemplified in the reaction of 2-methyl-l,3-butadiene with phenylacetylene (Eq. 12) [31]. 

Tab. 11.9 Rhodium complex-catalyzed coupling of various diynes with isocyanide.

Transition metal catalysts and biocatalysts can be combined in tandem in very effective ways as shown by the following example (Scheme 2.21). An immobilized rhodium complex-catalyzed hydrogenahon of 46 was followed by enzymatic hydrolysis of the amide and ester groups of 47 to afford alanine (S)-9 in high conversion and enanhomeric excess. Removal of the hydrogenation catalyst by filtration prior to addition of enzyme led to improved yields when porcine kidney acylase 1 was used, although the acylase from Aspergillus melleus was unaffected by residual catalyst [23]. 

N-alkinyldihydropyridone 72 yields bicyclic lactam 73 (92JA7292), and rhodium-complex-catalyzed intramolecular conjugate addition of vinylstan-nanes 74a and b (formed by aza-Diels-Alder reaction) leads to chiral piperidones 75a and b (08T3464). 

One of the success stories of transition metal catalysis is the rhodium-complex-catalyzed hydrogenation reaction. Asymmetric hydrogenation with a rhodium catalyst has been commercialized for the production of L-Dopa, and in 2001 the inventor, Knowles, together with Noyori and Sharpless, was awarded the Nobel Prize in chemistry. After the initial invention, (enantioselective) hydrogenation has been subject to intensive investigations (27). In general, hydrogenation reactions proceed... 

The rhodium complex [CpRh(bipy)Cl2] is reported (162) to act as one-half of a redox couple that, in concert with a manganese porphyrin system, catalyzes the epoxidation of olefins by dioxygen. In this two-phase system, the aqueous phase contains sodium formate, and the organic phase is a trichloroethane solution of [Mnm(tpp)]1+ and the rhodium complex (tpp = meso-tetraphenylporphyrin). Apparently, the rhodium complex catalyzes the reduction of [Mnin(tpp)]1+ by formate, and the manganese(II) species thus formed binds dioxygen and reacts with the substrate olefin to form the epoxide. However, the intermedi-... 

An important development in the past 15 years in hydroformylation technology was the introduction of biphasic homogeneous catalysis. Kuntz (62) expressed the basic idea of a new generation of water-soluble oxo catalysts with triphenylphosphane trisulfonate (tppts as the sodium salt) as a ligand for a rhodium-complex-catalyzed hydroformylation process. Ruhrchemie AG adapted the idea on the basis of research done at Rhone-Poulenc and developed it into an industrially viable process, which was... 

Monohydrides play an important role in the following rhodium-complex-catalyzed hydrogenations in aqueous media. The catalyst precursor is [RhCl(PTA)3], which gives the catalytically active species (HRh(PTA)3] formed by dehydrochlorination of the primary product of H2 oxidative addition (88). The complex is an active catalyst for several reactants, e.g., olefinic and oxo adds, allyl alcohol, and sulfostyrene. 

The chiral phosphine 31 or 32-rhodium complex catalyzed the addition of arystannanes 30 to N-sulfonylimines 29 to give diarylmethylamines 33 with high enantioselectivity (75-96% ee) [21]. The choice of the chiral monoden-tate phosphine ligand is essential for their catalytic asymmetric arylation. With chelating bisphosphine ligands the arylation was very slow. The authors hypoth-... 

Mechanism of Asymmetric Hydroformylation 7.2.2.L Rhodium Complex Catalyzed Reactions... 

The rest of the catalyst cycle is identical to that illustrated for the rhodium complex-catalyzed reactions in Scheme 1. It has been proposed that the asymmetric induction occurs during the formation of alkyl-Pt(CO)L2 intermediate through olefin insertion into the Pt-H bond [13]. 

Figure I. Ligand exchange is a proposed key step in the mechanism of phosphine-rhodium complex catalyzed hydroformylation of olefins...

The hydrosilylation of 3-butyn-l-ol, i.e. homopropargyl alcohol, with HSiMe2Ph catalyzed by (Cy3P)Pt(CH2=CH2)2 gives a 4.2 1 mixture of (E)-4-silyl- and (E)-3-silyl-3-buten-l-ols135, whereas the cationic rhodium complex-catalyzed reaction with HSiEt3 affords ( )-4-triethylsilyl-3-buten-l-ol (136) exclusively in 97% yield (equation 55)136. 

Metal-promoted vinylcyclopropane C3 - C5 ring expansions have been reported. Thus, ethyl 2-methoxy-2-vinylcyclopropanecarboxylate 393 rearranged to a 2 1 mixture of 3-methoxy-2-cyclopentenecarboxylate 396 and 3-methoxy-3-cyclopentene-carboxylate 397 on heating at 160 °C in the presence of catalytic amounts of copper bronze or copper(I) chloride in contrast, platinum and rhodium complexes catalyzed... 

FIGURE 27 Self-assembly of diphosphine catalyst for asymmetric rhodium-complex-catalyzed hydrogenation the catalyst contains titanium as the assembly metal (96). (For a color version of this figure, the reader is referred to the Web version of this chapter.)... 

Expansion of aziridines to -lactams. This rhodium complex catalyzes a regio-specific carbonylation of N-f-butyl-2-arylaziridines (1) to form lactams (2). The reaction fails if the alkyl group on nitrogen contains acidic hydrogens adjacent to nitrogen. 

Copper and rhodium complexes catalyze the reaction of alkenes with diazoacetate to give alkyl cyclopropanecarboxylates [13]. In the presence of Cu(acac)2, the reaction of carbohydrate enol ether 20 with methyl diazoacetate afforded a 1 4 mixture of cis- and frani-cyclopropanes 21 and 22 (c -product 21 was obtained with 95% de). When the reaction was catalyzed by CuOTf in the presence of hgand 23, the tranj -product 22 was obtained with 60% de (Scheme 10.4). The absolute configuration of the major diastereomer was not given [19]. 

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