Iridium boryl

One most important observation for the mechanistic discussion is the oxidative addition/insertion/reductive elimination processes of the iridium complex (31) (Scheme 1-10) [62]. The oxidative addition of catecholborane yields an octahedral iridium-boryl complex (32) which allows the anti-Markovnikov insertion of alkyne into the H-Ir bond giving a l-alkenyliridium(III) intermediate (34). The electron-... 

The remarkable stability of iridium-boryl complexes, as a function of the substituents on boron, is most likely responsible for the unique behavior of iridium in metal-promoted B-addition to unsaturated molecules. 

As with rhodium and platinum, iridium boryl systems have proved to be a valuable structural proving ground on which to establish fundamental properties of the BX2 ligand (Table 10). In a manner also mimicking rhodium, a significant body of work has emerged more recently due to the implication of iridium boryls in hydrocarbon activation [10,126,129,136-148,150,151, 155-159]... 

Table 10 Selected data for structurally characterized iridium boryl complexes ...

In 2011, Hartwig and coworkers reported the total synthesis of taiwaniaquinol B (55, Scheme 11.9), a member of a family of diterpenoids that are derived from the abietane skeleton [36]. A key aspect of the Hartwig synthesis of taiwaniaquinol B was the use of the iridium-catalyzed borylation reaction to accomplish the C(5) functionalization of resorcinol derivative 53. This regioselectivity for the overall bromination is complementary to that which would be obtained using a standard electrophilic aromatic substitution (EAS) reaction. In the transformation of 53 to 54, a sterically controlled borylation was first accomplished, which was then followed by treatment of the boronic ester intermediate with cupric bromide to... 

Remarkable carbon-boron bond-forming reactions are catalyzed by iridium complexes and proceed at room temperature with excellent regioselectivity, governed by steric factors. Heteroarenes are borylated in the 2-position and this reaction is generally tolerant of halide substituents on the arene (Equations (87) and (88)). 

Keywords Alkane metathesis Borylation C-H bond activation Dehydrogenation Hydroarylation Iridium catalyst Silylation... 

In the realm of C-H bond transformations applied toward the synthesis of fine chemicals, iridium has not achieved the prominence attained in recent years by the second-row platinum group metals, particularly palladium [10]. A notable exception, however, has been the leading role of iridium in the valuable chemistry of arene borylation [11]. 

Iridium-catalyzed formation of B-C bonds from arene C-H bonds was first reported by Smith and coworkers [73]. They demonstrated that the archetypal C-H activation products, Cp lr(PMe3)(H)(R), could mediate B-C bond formation (R = Ph, cyclohexyl) and were able to effect the catalytic borylation of benzene with HBpin (8) to produce CgHsBpin and H2 at 150°C (8). 

One of the most active and well-studied catalytic borylation systems is that generated from iridium(l) precursors such as [lr(COD)Cl]2 or [lr(COD)(OMe)]2 and bipyridine type ligands such as 2,2 -bipyridine or 4,4 -di-ferf-butyl-2,2 -bipyridine (dtbpy). In 2002, Ishiyama, Miyaura, and Hartwig et al. reported that the combination of [lr(COD)Cl]2 and 2,2 -bipyridine catalyzes arene borylation in the presence of excess arene under mild conditions (80°C). When the catalyst is generated from [lr(COE)2Cl]2 and dtbpy, the reaction proceeds even at room temperature [78, 79]. The same groups optimized conditions and found that the combination of [Ir(COD) (OMe)]2 and dtbpy (10) is a highly effective catalyst in the borylation of arenes so that reactions can be successfully performed with equimolar ratio of arenes and... 

Extensive studies of kinetics and isotope effects by Hartwig and coworkers support the mechanism shown in Scheme 5 for the lr(I)/dtbpy catalyzed borylation [81]. In particular, these studies indicate that the iridium(III) trisboryl bipyridine complex (10) is the species that activates the arene C-H bond this is in agreement with DFT calculations by Sakaki et al. predicting the key intermediacy of the trisboryl complex and the seven-coordinated Ir(V) species resulting from C-H addition [82]. C-H addition to Ir(III) was also proposed in the (Ind)Ir(COD)/ phosphine-catalyzed borylation by Smith et al. [76]. 

Scheme 5 Proposed mechanism for borylation by bipyridine ligated iridium complexes...

The [Ir(OMe)(COD)]2/dtbpy catalytic system borylates indole selectively at the 2-position (Scheme 6). Smith and coworkers reported that borylation of N-unprotected 2-substituted indoles exclusively occurs at 7-position (Scheme 6) [85, 86]. It has been suggested that nitrogen interaction with the iridium center or possibly the empty p-orbital of boron in a boryl ligand induces the observed regioselectivity. Borylation of other heteroarenes have been reported using the same or similar Ir(I) and bipyridine combination [85, 87-90]. 

It is no coincidence that the first X-ray structure analysis of a transition metal-boryl complex [8] was made on the iridium complex jac-[IrH2(BC8Hi4)(PMe3)3] (2) [9] derived from the B—H activation of the 9-borabicyclo[3.3.1]-nonane (9-BBN)... 

The beneficial effects of chelating ligands were also demonstrated by Hartwig, Ishiyama and Miyaura [62]. This group isolated the iridium(I) complex [lr(Bpin)3(COE)(DTBPY) modified with simple 2,2 -bipyridine ligands (such as 4,4 -di-tert-butyl-2,2 -bipyridine DTBPY), which seemed to be responsible for the first catalytic C—H borylation at room temperature (Scheme 7.30). An extension... 

Iridium-catalyzed borylation has also proved to develop the first general approach to functionalized unprotected indoles at the 7-position [67]. This selectivity can be explained by the nitrogen-directed aromatic borylation pathway in the mechanistic steps (Scheme 7.34). 

A convenient direct route has recently been described for obtaining regioregular polyalkylthiophenes using a tandem iridium-catalyzed borylation to produce the monomer, and a palladium-mediated coupling to produce the polymer [68]. The treatment of substituted thiophenes with B2pin2 in the presence of [lrCl2(COD)]2/ 4,4 -di-tert-butyl-2,2 -bipyridine (DTBPY) provided the expected monomer in 97% yield (Scheme 7.35). 

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