Cross-coupling silver® oxide

A catalytic version of the coupling was also developed, by using 10 mol % of CuCl2 and 20 mol % of sparteine 1 (silver chloride was used as a stoichiometric oxidant to regenerate the copper (II) oxidant). This catalytic system was applied to the asymmetric cross-coupling leading to 101 in a 41% yield and 32% ee. 

Oxidative cross-coupling reactions of alkylated derivatives of activated CH compounds, such as malonic esters, acetylacetone, cyanoacetates, and certain ketones, with nitroalkanes promoted by silver nitrate or iodine lead to the formation of the nitroalkylated products.67 This is an alternative way of performing SRN1 reactions using a-halo-nitroalkanes. 

Alkynyl halides are possible monomers for the cross-coupling polymerization, in which boronic acids are used as the organometallic counterparts. For example, bifunctional boronic acid 46 is allowed to react with l,4-di(bromoethy-nyl)benzene 138 to afford the corresponding PAE 139 as shown in Equation (64). Polymerization proceeds at room temperature in toluene in the presence of silver(i) oxide as an activator of the boron reagent. The polymer 139 is obtained in 30-50% yield showing color of red-brown to deep red-brown and slight solubility in toluene (<0.1 wt.%). The molecular weight (Mr of 139 was 1700-4300 (PDI = 1.3-3.6). 

Palladium-catalyzed dimerization of 2-arylpyridines by employing oxone as the terminal oxidant has been reported [75], The reaction was shown to proceed via a Pd(II)-Pd(TV) pathway. A method for cross-coupling of simple arenes with 2-arylpyridine derivatives by using catalytic palladium acetate in the presence of two equivalents of silver carbonate requires use of a large excess of the less reactive arene [76],... 

Trimethylsilyl compounds generally do not react in attempted cross couplings, but 2-trimethylsilylpyri-dines will react in the presence of TBAF and silver oxide. Also, 2-trimethylsilylpyridines containing chloro, fluoro or methoxy substituents will couple in the presence of a Cul additive. ... 

Many arylations are assisted by functional groups that promote ortho-metallation. Thus, for example, acetanihdes react with arylsilanes at the ortho position via pal-ladacycles 78 and 79 to form derivatives 80 (Scheme 11.27) [84]. Mechanistically, this transformation is similar to a cross-coupling reaction, in which the oxidative addition step is replaced by the ortho-metallation, although in this case the Pd(0) intermediate must be oxidized in situ to generate the reactive Pd(ll) species. Unsubstituted benzylamines and N-methylbenzylamine are ortho-arylated with Pd(OAc)2 in the presence of trifluoroacetic acid (TFA) and silver acetate [85], and a mechanism which differs from the usual Pd(0)/Pd(II) catalytic cycle was suggested for this. Ortho-alkylation was also observed in the palladium-catalyzed... 

Scheme 7.18 Cross-coupling reactions of aryl silanols promoted by silver(l) oxide.

Fused thiophene-cyclopentanes 39 can be synthesized by intramolecular dual C-H activation of 2-arylthiophenes 38 (Scheme 17, Table 10) [67]. The cross-coupling proceeds moderately well using palladium(ll) acetate as catalyst and silver (1) carbonate as oxidant. When the thiophene moiety is not substituted at positimi 2, homocoupling occurs easily. However, in contrast to this direct route, a two-step sequence consisting of a prior bromination and a subsequent palladium-catalyzed arylation is much more effective forming the fused thiophene-cyclopentane 39 in a yield of 83%. 

Heteroaryl phosphonates are common motifs in biological compounds and have stimulated the development of transition metal-catalyzed methodologies for C-P bond formation [68]. Phosphonated thiophenes 43 are accessible via silver-catalyzed dehydrogenative cross-coupling of thiophene 1 with dialkyl phosphites 42 (Scheme 19) [69]. The reaction is performed in aqueous dichloromethane, proceeds regioselectively at the a-position, and utilizes silver(l) nitrate as catalyst and the oxidant potassium persulfate. 

We reasoned that such a decarboxylation step could also be employed in a redox-neutral cross-coupling reaction with carbon electrophiles. On this basis, we drew up a catalytic cycle that starts with an oxidative addition of aryl halides or pseudohalides to a coordinatively unsaturated palladium(O) species f (Scheme 5). The more weakly coordinating the leaving group X, the easier should be its subsequent replacement by a carboxylate. At least for X = OTf, the palladium(ll) carboxylate h should form quantitatively, whereas for X = halide, it should be possible to enforce this step by employing silver or thallium salts as species g. The ensuing thermal decarboxylation of the palladium(ll) intermediate i represents the most critical step. Myers results indicated that certain palladium(ll) carboxylates liberate carbon dioxide on heating. However, it remained unclear whether arylpalladium (II) carboxylate complexes such as i would display a similar reactivity. If this were to be the case, they would form Ar-Pd-Ar intermediates k, which in turn are... 

This first plan for a decarboxylative cross-coupling carried with it certain weaknesses for potential industrial applications. It was to be expected that the salt metathesis between alkali metal carboxylates and late transition metal halides would be thermodynamically disfavored. We expected the formation of a palladium benzoate complex i from palladium bromide complexes c and potassium benzoate (g) to proceed well only in the presence of a stoichiometric quantity of silver to capture bromide ions [27]. However, we did not like the idea of using stoichiometric quantities of silver salts or of expensive aiyl triflates in the place of aryl halides. Finally, the published substrate scope of the oxidative Heck reactimi led to concerns that palladium catalysts mediate the decarboxylation rally of a narrow range of carboxylates, precluding use of this reaction as a general synthetic strategy. 

Silver(I) carbonate functioned as an oxidant in combination with TBAI to provide optimal yields. Pivalic acid was superior to pyridine as an additive. Thiazole, pyrazole, thiophene, and pyrrole substrates could be cross-coupled however, heteroarenes bearing electron-donating substituents afforded better yields compared with electron-withdrawing groups. The reactions proceeded in high regioselectivity at the C2/C5 position. 

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