Rhodium ketene complexes

In the reaction of the rhodium ketene complex 332 with t-BuC P the cycloadduct 333 is obtained in 79 % yield ". ... 

It has been reported that the chiral NMR shift reagent Eu(DPPM), represented by structure 19, catalyzes the Mukaiyama-type aldol condensation of a ketene silyl acetal with enantiose-lectivity of up to 48% ee (Scheme 8B1.13) [29-32]. The chiral alkoxyaluminum complex 20 [33] and the rhodium-phosphine complex 21 [34] under hydrogen atmosphere are also used in the asymmetric aldol reaction of ketene silyl acetals (Scheme 8BI. 14), although the catalyst TON is quite low for the former complex. 

If rhodium enolates are used in a catalytic cycle they can promote aldol reactions under reasonably mild conditions. For example, the aldol reactions of trimethylsilyl enol ethers and ketene silyl acetals (37) with aldehydes can be catalyzed by various rhodium(I) complexes, under essentially neutral conditions, to give p-trimethylsiloxy ketones and esters (38 equation 14 and Table 6). The study of Matsuda and coworkers suggests that use of the rhodium complex Rlu(CO)i2 (39 at 2 mol %) in benzene at 100 C gives best results for the formation of adduct (38 Table 6, entries 1-7). There is negligible diastereoselectivity in most cases. Various cationic ihodium complexes such as (40) also catalyze the reaction. Reetz and Vougioukas have found that this aldol reaction proceeds well with the more reactive ketene silyl acetals, (37) for R = OMe or OEt, in CH2CI2 at room temperature (Table 6, entries 8-13). The intermediacy of an ti -O-bound rhodium enolate, such as (41), in the catalytic cycle is like-... 

If rhodium enolates are used in a catalytic cycle they can promote aldol reactions under reasonably mild conditions. For example, the aldol reactions of trimethylsilyl enol ethers and ketene silyl acetaU (37) with aldehydes can be catalyzed by various rhodium(I) complexes, under essentially neutral conditions, to give p-trimethylsiloxy ketones and esters (38 equation 14 and Table The study of... 

The transition metal-catalyzed cyclopropanation of alkenes is one of the most efficient methods for the preparation of cyclopropanes. In 1959 Dull and Abend reported [617] their finding that treatment of ketene diethylacetal with diazomethane in the presence of catalytic amounts of copper(I) bromide leads to the formation of cyclopropanone diethylacetal. The same year Wittig described the cyclopropanation of cyclohexene with diazomethane and zinc(II) iodide [494]. Since then many variations and improvements of this reaction have been reported. Today a large number of transition metal complexes are known which react with diazoalkanes or other carbene precursors to yield intermediates capable of cyclopropanating olefins (Figure 3.32). However, from the commonly used catalysts of this type (rhodium(II) or palladium(II) carboxylates, copper salts) no carbene complexes have yet been identified spectroscopically. 

Quite recently, Doyle and coworkers found that dirhodium(II) complexes such as rhodium(II) acetate and Rh2(4S-MEAZ)4 (14) also act as highly active Lewis addcatalysts (1 mol%) for the reaction of trimethylsilylketene and ethyl glyoxalate, affording the P-lactonel5 (Table4.6) [42]. However, theuseofthechiral Rh-complex, Rh2(4S-M EAZ)4, alone afforded almost no asymmetric induction (5% ee for (S)-isomer) (entry 2). The use of quinine (10 mol%) as a cobase catalyst to activate the ketene simultaneously provided exceptional enantiocontrol (99% ee) and enhanced reactivity (entry 5). 

A small number of enantiomerically pure Lewis acid catalysts have been investigated in an effort to develop a catalytic asymmetric process. Initial work in this area was carried out by Narasaka and coworkers using the titanium complex derived from diol (8.216) in the cycloaddition of electron-deficient oxazolidinones such as (8.217) with ketene dithioacetal (8.218), alkenyl sulfides and alkynyl sulfides. Cyclic alkenes can be used in this reaction and up to 73% ee has been obtained in the [2- -2] cycloaddition ofthioacetylene (8.220) and derivatives with2-methoxycarbonyl-2-cyclopenten-l-one (8.221) usingthe copper catalyst generated with bis-pyridine (8.222). Furthermore, up to 99% ee has been obtained in the [2-1-2] cycloaddition of norbornene with alkynyl esters using rhodium/Hs-BINAP catalysts. This reaction is not restricted to the use of transition metal-based Lewis... 

Rhodium(I)-catalysed 2 + 2 + 2-cycloadditions of ene-allene (96) with allene (97) yielded trans-fused hydrindanes (98) and decalins with high regio- and stereo-selectivities (Scheme 31). A Ni-phosphine complex catalysed the 2 + 2 + 2- (g) cycloaddition of diynes with substituted ketenes to produce 2,4-cyclohexadienones in high yields. No decarbonylation products were observed. The chiral A-heterocyclic carbene-catalysed enantioselective 2 + 2 + 2-cycloaddition of ketenes with CS2 produced l,3-oxatian-6-ones in good yields and with high enantioselectivities. 2" ... 

Rhodium catalyzed alkyne oxidation is proposed to effect ketene generation from 4-methoxyphenylacetylene with oxygen transfer from pyridine N-oxides, with capture of the rhodium complexed ketene 32 by nucleophiles, including phenols and amines (Scheme 4.11). In the presence of... 

Enol ethers could be used as gaseous alkyne (acetylene and propyne) equivalents, and liquid ketene acetal could be used as a stable equivalent of unstable gaseous ethynyl methyl ether in cationic rhodium(I)/BINAP complex-catalyzed [2 -1- 2 - - 2] cycloaddition (Scheme 4.46) [49]. 

The first cross-reaction between the terminal silylacetylene (166) and two ketene molecules, giving rise to 1,3-enynes (167), has been attained using a cationic rhodium complex catalyst. ... 

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