Heteroatomic coupling oxidative addition

In this Stille coupling, oxidative addition to 23 might take place in two positions. The carbon atom between the two ring heteroatoms has the more positive partial charge which makes its carbon-triflate bond more susceptible to oxidative addition thus providing product 24 regioselectively. 

Cross-coupling to form carbon heteroatom bonds occurs by oxidative addition of an organic halide, generation of an aryl- or vinylpalladium amido, alkoxo, tholato, phosphido, silyl, stannyl, germyl, or boryl complex, and reductive elimination (Scheme 2). The relative rates and thermodynamics of the individual steps and the precise structure of the intermediates depend on the substrate and catalyst. A full discussion of the mechanism for each type of substrate and each catalyst is beyond the scope of this review. However, a series of reviews and primary literature has begun to provide information on the overall catalytic process.18,19,22,23,77,186... 

Examples of catalytic formation of C-C bonds from sp C-H bonds are even more scarce than from sp C-H bonds and, in general, are limited to C-H bonds adjacent to heteroatoms. A remarkable iridium-catalyzed example was reported by the group of Lin [116] the intermolecular oxidative coupling of methyl ethers with TBE to form olefin complexes in the presence of (P Pr3)2lrH5 (29). In their proposed mechanism, the reactive 14e species 38 undergoes oxidative addition of the methyl C-H bond in methyl ethers followed by olefin insertion to generate the intermediate 39. p-hydride elimination affords 35, which can isomerize to products 36 and 37 (Scheme 10). The reaction proceeds under mild condition (50°C) but suffers from poor selectivity as well as low yield (TON of 12 after 24 h). 

Following the oxidative addition, in the transmetalation step the anionic form of the heteroatom containing coupling partner (amide, alkoxide) is transferred onto the palladium, which is usually achieved by the combined use of the neutral form of the nucleophile and a suitable base. The choice of the proper base might be crucial for the success of the coupling. The transmetalation, as depicted in Figure 2-3, usually follows a coordination-... 

The general catalytic cycle for this carbonylation coupling reaction is analogous to direct carbon-heteroatom coupling [scheme (39)] except that carbon monoxide insertion takes place after the oxidative addition step and prior to the nucleophilic attack of the amine [scheme (40)] ... 

Cross-coupling of Ar(or vinyl)-X with organometaDic species, terminal alkynes, and olefins, as well as carbonylation in the presence of nucleophiles, represent well-known synthetic routes for C—C bond formation. As far as C-heteroatom bond formation is concerned, powerful synthetic procedures have been developed for selective formation of the C-P (P = R2P, R2P(0), R(R 0)P(0), (R0)2P(0)), C-SR, C SeR, C—NR2, and so on, bonds. All of these catalytic methods are based on substitution reactions. The catalytic cycle of a typical substitution reaction includes the following stages (i) oxidative addition, (ii) transmetaUation, and (iii) C-heter-oatom reductive elimination. 

The reaction of certain palladium-heteroatom complexes to alkenes and alkynes is a versatile tool for the synthesis of alkanes and alkene having heteroatoms attached. In particular, the various B-B, B-Si, and B-Sn compounds can be used for palladium-catalyzed borylation of alkenes and alkynes (Scheme 5-2). Borostannylation takes place at ambient temperature, whereas silylboration " only proceeds at a temperature above 80 °C due to the slow oxidative addition of a B-Si bond to a palladium(O) catalyst. Both reactions selectively provide cz j-products via addition of silicone or tin to the internal carbon and boron. The reactions are compatible with various functional groups for both terminal and internal alkynes. Cross-coupling reaction of boranes with organic halides selectively occurs at the terminal C-B bonds to provide regiodefined and stereodefined alkenylboron, alkenylsilicon, and alkenyltin compounds. 

Another compound 9 with three heterocyclic rings linearly fused (5 5 5) with two heteroatoms has been prepared from 1,1 -carbonyl diindole 297 <2001T5199>. Palladium-mediated coupling of the 2- and 2 -positions of 297 afforded the 1,1 -carbonyl-2,2 -biindolyl 9. 1,1 -Carbonyl diindole 297 was in turn obtained in 41% yield from 1,1 -carbonyldiimidazole 296 by reaction with indole in DMSO at 125 °C. The palladium-catalyzed coupling step afforded the desired product 9 in low yield and required a stoichiometric amount of palladium acetate. Therefore, it was felt prohibitively expensive. Addition of various co-oxidants (Ac20, Mn02, and Cu(OAc)2, etc) to make the reaction catalytic in palladium did not result in any improvement of the yield of 18 (Scheme 53). 

Electron transfer from the alkene leads to a radical cation that can undergo coupling (Scheme la). The radical cation can also react with the nucleophilic heteroatom of a reagent to afford addition or substitution products (Scheme lb). Adducts can be likewise obtained by oxidation of the nucleophile to a radical that undergoes radical addition. Reactions between alkenes and nucleophiles can be realized too with chemical oxidants that are regenerated at the anode (mediators) (see Chapter 15). Finally, cycloadditions between alkenes can be initiated by a catalytic anodic electron transfer. These principal reaction modes are subsequently illustrated by selected conversions. 

The same transition metal systems which activate alkenes, alkadienes and alkynes to undergo nucleophilic attack by heteroatom nucleophiles also promote the reaction of carbon nucleophiles with these unsaturated compounds, and most of the chemistry in Scheme 1 in Section 3.1.2 of this volume is also applicable in these systems. However two additional problems which seriously limit the synthetic utility of these reactions are encountered with carbon nucleophiles. Most carbanions arc strong reducing agents, while many electrophilic metals such as palladium(II) are readily reduced. Thus, oxidative coupling of the carbanion, with concomitant reduction of the metal, is often encountered when carbon nucleophiles arc studied. In addition, catalytic cycles invariably require reoxidation of the metal used to activate the alkene [usually palladium(II)]. Since carbanions are more readily oxidized than are the metals used, catalysis of alkene, diene and alkyne alkylation has rarely been achieved. Thus, virtually all of the reactions discussed below require stoichiometric quantities of the transition metal, and are practical only when the ease of the transformation or the value of the product overcomes the inherent cost of using large amounts of often expensive transition metals. 

The coupling of an allyl or acyl moiety onto carbon atoms is achieved by anodic oxidation of a-heteroatom substituted organostannanes or Oj -acetals in the presence of allylsilanes or silyl enol ethers. The reaction probably involves carbocations as intermediates that undergo electrophilic addition to the double bond [245c]. 

For these syntheses the 7i-bond is formed via an elimination reaction involving either two protons (electrochemical oxidation), or one proton and one or two heteroatoms. In addition, the a- and n-bonds can be forced simultaneously by a coupling reaction of two carbenes. 

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