Intermolecular reactions oxidative coupling

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). 

Since enol silyl ethers are readily accessible by a number of methods in a regioselective manner and since the trialkylsilyl moiety as a potential cationic leaving group facilitates the termination of a cyclization sequence, unsaturated 1-trialkylsilyloxy-1-alkenes represent very promising substrates for radical-cation cyclization reactions. Several methods have been reported on the synthesis of 1,4-diketones by intermolecular oxidative coupling of enol silyl ethers with Cu(II) [76, 77], Ce(IV) [78], Pb(IV) [79], Ag(I) [80] V(V) [81] or iodosoben-zene/BFa-etherate [82] as oxidants without further oxidation of the products. 

Palladium(0)-catalyzed cross-coupling of aryl halides and alkenes (i.e., the Heck reaction) is widely used in organic chemistry. Oxidative Heck reactions can be achieved by forming the Pd -aryl intermediate via direct palladation of an arene C - H bond. Intramolecular reactions of this type were described in Sect. 4.1.2, but considerable effort has also been directed toward the development of intermolecular reactions. Early examples by Fu-jiwara and others used organic peroxides and related oxidants to promote catalytic turnover [182-184]. This section will highlight several recent examples that use BQ or dioxygen as the stoichiometric oxidant. 

Although arylation or alkenylation of active methylene compounds can be carried out using a Cu catalyst, the reaction is sluggish. However, the arylation of malononitrile (390) or cyanoacetate proceeds smoothly in the presence of a base and Pd catalysts [189], Tetracyanoquinodimethane (392) is prepared by the coupling of / -diiodoben-zene with malononitrile (390) to give 391, followed by oxidation [190], Presence of the cyano group seems to be essential for intermolecular reactions. However, the intramolecular arylation of malonates, / -keto esters and /i-diketones proceeds smoothly [191]. The bromoxazole 393 reacts with phenylsulphonylacetonitrile (394)... 

Many cyclization reactions via formation of metallacycles from alkynes and alkenes are known. Formally these reactions can be considered as oxidative cyclization (coupling) involving oxidation of the central metals. Although confusing, they are also called the reductive cyclization, because alkynes and alkenes are reduced to alkenes and alkanes by the metallacycle formation. Three basic patterns for the intermolecular oxidative coupling to give the metallacyclopentane 94, metallacyclopentene 95 and metallacyclopentadiene 96 are known. (For simplicity only ethylene and acetylene are used. The reaction can be extended to substituted alkenes and alkynes too). Formation of these metallacycles is not a one-step process, and is understood by initial formation of an tj2 complex, or metallacyclopropene 99, followed by insertion of the alkyne or alkene to generate the metallacycles 94-96, 100 and 101-103 (Scheme 7.1). 

A serendipitous use of a chiral auxiliary in atrop-selective biaryl bond formation has recently been published by Kita and co-workers [39, 137]. With diaryl substrate 201, which is related to precursors of the ellagitannins (see Section 14.6.1), PIFA-mediated oxidative coupling did not lead to the expected ellagitannin structure 202 (Scheme 50). Rather surprisingly, this reaction proceeds with intermolecular Ar-Ar bond formation. The chiral glucose framework efficiently transfers stereochemical information, but not in a intramolecular closure. 

Reaction of electron-rich aromatic compounds with TTFA leads to intermolecular oxidative coupling to form the corresponding biaryls without aromatic thallation. The reaction proceeds through one-electron transfer from aromatic compounds to Tl(III) to give an aromatic radical cation which leads to biaryls (Schemes 9.52 and 9.53 [52]). Intramolecular aryl coupling also occurs (Schemes 9.54 [53] and 9.55 [54]) and, further, when the carboxylic acid moiety is present, intramolecular as well as intermolecular lactonization occurs (Schemes 9.56 [55] and 9.57 [56]). 

Intermolecular dehydrogenative oxidative homocouplings of (hetero)arenes turned out to be among the most important methods for the synthesis of symmetrically substituted biaryls [122]. A recent illustrative example is oxidative coupling reactions of 2-naphthols, which were accomplished in an asymmetric fashion employing an inexpensive iron catalyst (Scheme 9.47) [123]. 

In a related study, intramolecular oxidative coupling of enolate derivatives has been investigated by Schmittel and co-workers [167]. The intermolecular version of this reaction provides a useful route to 1,4-dicarbonyl compounds but typically suffers from low levels of stereoselectivity. Furthermore, in mixed systems, the desired heterocoupling products are often accompanied by appreciable amounts of homocoupling products. It was hoped that the use of a single metal for both enolate precursors with concomitant intramolecularization of the bond-forming event might overcome some of these problems. 

Previously, Itoh and co-workers presented the importance of substrate coordination to the CU2O2 core in intermolecular oxidative reactivity. The reaction of /(-substituted neutral phenols with a side-on peroxo dicopper(II) complex supported by a tridentate ligand results in oxidative coupling... 

The direct nucleophilic substitution of electron-rich phenol ethers using hypervalent iodine oxidants in the presence of Lewis acid or fluorinated alcohols and involving aromatic cation-radical intermediates was originally developed by Kita and coworkers in 1994 [362], Since then this procedure with some variations has been extensively applied by Kita and other researchers for various oxidative transformations. In the intermolecular mode, this reaction (Scheme 3.122) has been utilized for the preparation of the products 298 from N3, AcO , ArS, SCN , 3-dicarbony 1 compounds and other external nucleophiles [320]. The oxidative coupling reaction in the intramolecular mode provides a powerful synthetic tool for the preparation of various... 

Only a few examples of hypervalent iodine-catalyzed reactions leading to the formation of new C-C bonds have been reported. In seminal work, Kita and coworkers reported in the 2005 a single example of an intermolecular C-C bond formation reaction catalyzed by an iodoarene [2]. Specifically, the oxidative coupling of phenolic ether 70 using [bis(trifiuoroacetoxy)iodo]benzene as a catalyst and mCPBA as a terminal oxidant afforded product 71 in moderate yield (Scheme 4.35). 

Terminal alkynes undergo oxidative coupling in the presence of the GuGl-TMEDA catalytic system in [G4GiIm]PF6 under aerobic conditions to produce 1,3-diynes. " Intermolecular Pauson-Khand reactions of strained alkenes with alkynes and Go2(GO)g were performed in [G4GiIm]PF6 either thermally or in the presence of... 

Intermolecular reaction of l-iodo-2,3-dimethoxybenzene (134) with the vinyl bromide 140 (10 equiv.) gave a mixture of 141 and 142 [37]. In this reaction, oxidative addition of 140 to the palladacycle 143 generates 144, and the coupled product 145 is formed by reductive elimination. Finally 5-exo cyclization of 145 and -H elimination afford 141. 

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