Alkynes rhodium reactions

Oshima et al. explored a cationic rhodium-catalyzed intramolecular [4+2] annulation of l,3-dien-8-ynes in water in the presence of sodium dodecyl sulfate (SDS), an anionic surfactant.132 When the substrate l,3-dien-8-yne was a terminal alkyne, the reaction provided an inter-molecular [2+2+2] product (Eq. 4.68). In water, a reactive cationic rhodium species was formed by the dissociation of the Rh-Cl bond in the presence of SDS. The SDS forms negatively charged micelles, which would concentrate the cationic rhodium species (Scheme 4.15). 

The development of the first alkyne silylformylation reaction was reported in 1989 by Matsuda [27]. Alkynes were treated with Me2PhSiH and Et3N with 1 mol% Rh4(CO)i2 under CO pressure to produce yS-silyl-a,/ -unsaturated aldehydes (Scheme 5.20). A second report from Ojima detailed the development of rhodium-cobalt mixed metal clusters as effective catalysts for alkyne silylformylation [28]. Shortly thereafter, Doyle reported that rhodium(II) perfluorobutyrate was a highly efficient and selective catalyst for alkyne silylformylation under remarkably mild reaction conditions (0°C, 1 atm CO) [29]. In all these reports, terminal alkynes react regiospedfically with attachment of the silane to the unsubstituted end of the alkyne. The reaction is often (but not always) stereospecific, producing the cis-product preferentially. 

A tetrahydrofuran fused with a seven-membered ring was obtained from an enyne through a [5+2] cycloaddition reaction catalyzed by [(C10H8)Rh(COD)]+ SbF6 complex <02AG(E)4550>. Rhodium-catalyzed carbonylative alkene-alkyne coupling reactions... 

An efficient single-step synthesis of isoquinolines was achieved by a three-component reaction of aromatic ketone with benzylamine and alkyne. Rhodium (I) is used as the catalyst and o-functionalization of the aromatic rings is not necessary, indicating an extended scope for this method <03OL2759>. The reaction is complicated by a sizable amount of phenethyl-substituted side product. 

Shibata et al. reported that, in the presence of an iridium catalyst, the carbonylative alkyne—alkyne coupling reaction of the diyne 102 with carbon monoxide gave the tetrahydrofuran-fused cyclopen-tadienone 103 (Scheme 35).114 The rhodium-catalyzed alkyne—alkyne coupling reaction of 102 with the isocyanide 104 produced the iminocyclopentadiene 105 (Scheme 36).114b These reactions proceed through formation of the metallacyclopentadiene intermediate 106, which undergoes insertion either of CO or of the isocyanide 104. 

Cyclopropenation. Cyclopropenes can be formed from alkynes by reaction with methyl diazoacetate using a rhodium(ll) carboxylate as catalyst. The reaction is not particularly subject to steric hindrance, but polar groups (CH2COOCH3) inhibit cyclopropenation markedly. Insertion reactions compete with cyclopropenation in the case of acetylenic alcohols. ... 

A tunable rhodium-catalyzed intramolecular alkyne insertion reaction proceeding through the C-C cleavage of benzocyclobutenones was used to synthesize a variety of fused P-naphthol and indene scaffolds with dihydrobenzo[c]furan motifs (14AGE1674). 

Remarkable chemoselectivity was also observed when alkyne-tethered electron-deficient olefins 158 were employed as substrates (Scheme 8.44) [123]. Rhodium/ diene catalysis led preferentially to carborhodation of the alkyne, followed by 1,4-addition to the a,P-unsaturated moiety to provide adducts 159 in high yield and excellent enantioselectivity. The difference between phosphines and chiral dienes as ligands in this reaction setting was striking. Whereas, rhodium-bisphosphines complexes catalyzed the 1,4-addition to a,P-enoates more effectively than the aryla-tion of alkynes, rhodium/diene catalysts favored the arylation of alkynes over the 1,4-addition. 

The same ruthenium(II) catalytic system with 1 equiv. of Cu(0Ac)2-H20 oxidant was used to generate 2-pyridones directly firom acrylamides by C-H and N-H bond functionalization and annulation with alkynes. This reaction offers improved substrate scope with respect to the similar reaction reported with rhodium catalyst [(Eq. 88)] [177]. The reaction is applicable to dialkylacetylenes. Alkylphenyla-cetylenes lead to regioselective annulation with an (aryl)C-N linkage formation, consistent with the coupling of the electron-deficient alkyne carbon with the electron-rich carbon of the Ru-C bond. 

Almost simultaneously, Hua and co-workers developed a versatile and straightforward route to construct multisubstituted isoquinolines and relative fused pyridine heterocycles (60) by using readily availableketones (59) and alkynes (Scheme 7.41) [110]. The reaction involves condensation of aryl ketones and hydroxylamine, rhodium(III)-catalyzed C-H bond activation of the in situ generated aryl ketone oximes, and cycUzation with internal alkynes. This reaction proceeds under external-oxidant-free and moderately mild conditions. Later, a similar one-pot multi-component process promoted by a Rh(III) catalyst that generates substituted isoquinolines under microwave irradiation conditions was uncovered by Jun [111]. 

The direct combination of selenium and acetylene provides the most convenient source of selenophene (76JHC1319). Lesser amounts of many other compounds are formed concurrently and include 2- and 3-alkylselenophenes, benzo[6]selenophene and isomeric selenoloselenophenes (76CS(10)159). The commercial availability of thiophene makes comparable reactions of little interest for the obtention of the parent heterocycle in the laboratory. However, the reaction of substituted acetylenes with morpholinyl disulfide is of some synthetic value. The process, which appears to entail the initial formation of thionitroxyl radicals, converts phenylacetylene into a 3 1 mixture of 2,4- and 2,5-diphenylthiophene, methyl propiolate into dimethyl thiophene-2,5-dicarboxylate, and ethyl phenylpropiolate into diethyl 3,4-diphenylthiophene-2,5-dicarboxylate (Scheme 83a) (77TL3413). Dimethyl thiophene-2,4-dicarboxylate is obtained from methyl propiolate by treatment with dimethyl sulfoxide and thionyl chloride (Scheme 83b) (66CB1558). The rhodium carbonyl catalyzed carbonylation of alkynes in alcohols provides 5-alkoxy-2(5//)-furanones (Scheme 83c) (81CL993). The inclusion of ethylene provides 5-ethyl-2(5//)-furanones instead (82NKK242). The nickel acetate catalyzed addition of r-butyl isocyanide to alkynes provides access to 2-aminopyrroles (Scheme 83d) (70S593). 

Similar reactions have been carried out on acetylene. Aldehydes add to alkynes in the presence of a rhodium catalyst to give conjugated ketones. In a cyclic version of the addition of aldehydes, 4-pentenal was converted to cyclopen-tanone with a rhodium-complex catalyst. In the presence of a palladium catalyst, a tosylamide group added to an alkene unit to generate A-tosylpyrrolidine derivatives. ... 

The reaction of alkenes with alkenes or alkynes does not always produce an aromatic ring. An important variation of this reaction reacts dienes, diynes, or en-ynes with transition metals to form organometallic coordination complexes. In the presence of carbon monoxide, cyclopentenone derivatives are formed in what is known as the Pauson-Khand reaction The reaction involves (1) formation of a hexacarbonyldicobalt-alkyne complex and (2) decomposition of the complex in the presence of an alkene. A typical example Rhodium and tungsten ... 

The syntheses and spectroscopic and electrochemical characterization of the rhodium and iridium porphyrin complexes (Por)IVI(R) and (Por)M(R)(L) have been summarized in three review articles.The classical syntheses involve Rh(Por)X with RLi or RMgBr, and [Rh(Por) with RX. In addition, reactions of the rhodium and iridium dimers have led to a wide variety of rhodium a-bonded complexes. For example, Rh(OEP)]2 reacts with benzyl bromide to give benzyl rhodium complexes, and with monosubstituted alkenes and alkynes to give a-alkyl and fT-vinyl products, respectively. More recent synthetic methods are summarized below. Although the development of iridium porphyrin chemistry has lagged behind that of rhodium, there have been few surprises and reactions of [IrfPorih and lr(Por)H parallel those of the rhodium congeners quite closely.Selected structural data for rr-bonded rhodium and iridium porphyrin complexes are collected in Table VI, and several examples are shown in Fig. 7. ... 

The NHCs have been used as ligands of different metal catalysts (i.e. copper, nickel, gold, cobalt, palladium, rhodium) in a wide range of cycloaddition reactions such as [4-1-2] (see Section 5.6), [3h-2], [2h-2h-2] and others. These NHC-metal catalysts have allowed reactions to occur at lower temperature and pressure. Furthermore, some NHC-TM catalysts even promote previously unknown reactions. One of the most popular reactions to generate 1,2,3-triazoles is the 1,3-dipolar Huisgen cycloaddition (reaction between azides and alkynes) [8]. Lately, this [3h-2] cycloaddition reaction has been aided by different [Cu(NHC)JX complexes [9]. The reactions between electron-rich, electron-poor and/or hindered alkynes 16 and azides 17 in the presence of low NHC-copper 18-20 loadings (in some cases even ppm amounts were used) afforded the 1,2,3-triazoles 21 regioselectively (Scheme 5.5 Table 5.2). 

A similar coupling reaction of salicyl aldehydes with disubstituted alkynes, catalyzed by rhodium, is known... 

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