Phosphines, electron-rich

In the coupling of the allenyl ester 7 with a terminal alkyne, an electron-deficient phosphine (Ph3P) gave the enyne-conjugated ester 8 as the major product, while an electron-rich phosphine (TDMPP or TTMPP) yielded the non-conjugated enyne esters ( )- and (Z)-9[4],... 

Buchwtild and co-workers have developed highly aedve cattilysts consisting of bulky, electron-rich phosphine ligands v/ith a biphenyl backbone combined v/ith PdfOAci for the aryladon of ketones or niiroalkanes fEq 5 73 ... 

More recently, a new metathesis catalyst involving a ruthenium-alkylidene complex with a sterically bulky and electron-rich phosphine ligand has been synthesized and applied to RCM in aqueous media (Figure 3.5).197 This catalyst has the benefit of being soluble in almost... 

A novel potentially useful route for the synthesis of metallo-silanols is based on the reaction of metallohydridosilanes with 1,1-dimethyldioxirane [7,8] resulting in the insertion of oxygen into the Si-H bond. This procedure is supplementary to the hydrolysis route, since, in addition to the transformation of the "normal" ferrio-hydridosilanes 9a,b to the silanols 10a,b, it guarantees the formation of chiral 10c, not available by hydrolysis, from "electron rich" phosphine iron fragment substituted 9c (Eq. (2)). 

Fundamentally, the high nucleophilicity of stable carbenes, coupled with the tendency to increase the coordination number at the carbenic carbon, renders their chemical behavior very similar to that of electron-rich phosphines. As such, they have aroused considerable interest as ligands in p-, cl-, and / -block chemistry. Earlier reviews (7a,b) have covered some aspects of the main group chemistry of stable nucleophilic carbenes however, there has been considerable recent activity in this field, and thus a comprehensive, up-to-date review was considered desirable. 

C-H functionalizations of benzimidazoles have been described and are thought to involve an Rh(m) hydride. Hydrochloride salts of bulky electron-rich phosphines were found to be useful additives (Equations (115) and (116)). 

There is certain similarity in the order of reactivities between SnAt displacement reactions and oxidative additions in palladium chemistry. Therefore, the ease with which the oxidative addition occurs for these heteroaryl chlorides has a comparable trend. Even a- and y-chloroheterocycles are sufficiently activated for Pd-catalyzed reactions, whereas chlorobenzene requires sterically hindered, electron-rich phosphine ligands. 

Recently, the groups of Fu and Buchwald have coupled aryl chlorides with arylboronic acids [34, 35]. The methodology may be amenable to large-scale synthesis because organic chlorides are less expensive and more readily available than other organic halides. Under conventional Suzuki conditions, chlorobenzene is virtually inert because of its reluctance to oxidatively add to Pd(0). However, in the presence of sterically hindered, electron-rich phosphine ligands [e.g., P(f-Bu)3 or tricyclohexylphosphine], enhanced reactivity is acquired presumably because the oxidative addition of an aryl chloride is more facile with a more electron-rich palladium complex. For... 

The success of Burk s alkyl diphosphines spurred development of a number of other ligands with electron rich phosphines, such as Zhang s PennPHOS (7) [36-38], Marinetti s /Pr-CnrPHOS (8) [39], and Imamoto s BisP ligands (9) [40],... 

There are a few exceptions amongst the cationic complexes that also undergo oxidative addition of dihydrogen prior to alkene complexation. Alkylphosphines, raising the electron density on the rhodium cation, have been shown to belong to these exceptions, which seems logical [16] electron-rich phosphine complexes can undergo oxidative addition of H2 before the alkene coordinates to the rhodium metal. 

The fact that complex 38 does not react further - that is, it does not oxidatively add the N—H bond - is due to the comparatively low electron density present on the Ir center. However, in the presence of more electron-rich phosphines an adduct similar to 38 may be observed in situ by NMR (see Section 6.5.3 see also below), but then readily activates N—H or C—H bonds. Amine coordination to an electron-rich Ir(I) center further augments its electron density and thus its propensity to oxidative addition reactions. Not only accessible N—H bonds are therefore readily activated but also C—H bonds [32] (cf. cyclo-metallations in Equation 6.14 and Scheme 6.10 below). This latter activation is a possible side reaction and mode of catalyst deactivation in OHA reactions that follow the CMM mechanism. Phosphine-free cationic Ir(I)-amine complexes were also shown to be quite reactive towards C—H bonds [30aj. The stable Ir-ammonia complex 39, which was isolated and structurally characterized by Hartwig and coworkers (Figure 6.7) [33], is accessible either by thermally induced reductive elimination of the corresponding Ir(III)-amido-hydrido precursor or by an acid-base reaction between the 14-electron Ir(I) intermediate 53 and ammonia (see Scheme 6.9). 

Hydroboration and hydrosilylation reactions ofalkynes, when they do not proceed spontaneously, can be catalyzed by numerous transition metals [17]. Metal vinyli-dene-mediated processes uniquely provide (Z)-alkenes via trans-addition . In 2000, Miyaura and coworkers discovered that both Rh(I)- and Ir(I)-complexes supported by bulky electron-rich phosphine ligands catalyze the hydroboration of terf-butylacety-lene to give alkenylboronate 41 with >95 5 Z/E selectivity (Equation 9.5) [18]. 

The catalyst prepared from PPh3 and a simple Ir(I) salt, [IrCl(cod)]2, promotes ( )-selective head-to-head dimerization in good yield, while the combination of [IrCl (cod)]2 with an electron-rich phosphine (PPrj) affords (Z)-enynes with reduced efficiency, but comparable selectivity. The results of [rrCl(cod)]2/PPr3-catalyzed dimerization reactions carried out according to Scheme 9.10 are summarized in Table 9.10. 

The need for a base additive in this reaction implies the intermediacy of acetylide complexes (Scheme 9.10). As in the Rh(III)-catalyzed reaction, vinylidene acetylide S4 undergoes a-insertion to give the vinyl-iridium intermediate 55. A [l,3]-propargyl/ allenyl metallatropic shift can give rise to the cumulene intermediate 56. The individual steps of Miyaura s proposed mechanism have been established in stoichiometric experiments. In the case of ( )-selective head-to-head dimerization, vinylidene intermediates are not invoked. The authors argue that electron-rich phosphine ligands affect stereoselectivity by favoring alkyne C—H oxidative addition, a step often involved in vinylidene formation. 

Tetrahydrobis(benzofuran) is produced by a tandem cyclization reaction from the bis-vinyl ether on reaction with catalytic quantities of rhodium(l) salts in the presence of electron-rich phosphine ligands <20030L1301>. Thus, employing 10mol% of [RhCl(coe)2]2 with 20mol% of a dicyclohexyl ferrocenyl phosphine ligand produces the bis-cyclized product (coe = cyclooctene Equation 67). 

Transition-metal-catalyzed synthesis of poly(arylene)s via carbon-carbon coupling reactions was started by Yamamoto et al. three decades ago [52,53] since then various carbon-carbon bond formation processes with transition-metal catalysts have been applied to polycondensation [54-57]. In recent years, Buchwald et al. and Hartwig et al. developed Pd-catalyzed amination and etherification of aromatic halides by using bulky, electron-rich phosphine ligands [58-60], and this chemistry has been applied to polycondensation for... 

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