Oxidative addition reversible

The general stoichiometry of the reaction is shown in Scheme 1. The equilibrium reaction defining the first step (forward = oxidative addition reverse = reductive elimination) was verified previously. Figure 1 illustrates the oxidative addition of Mel to [RhCl(CO)(Y(p-Tol)3 2]. 

Reaction pathways usually involve only 16- and 18-electron species or intermediates. Complexes of 18 electrons undergo ligand dissociation, reductive elimination, insertion, and oxidative coupling, whereas 16-electron complexes undergo ligand association, oxidative addition, reversal of insertion type, and reductive coupling reactions. These two mechanisms lead to different types of synthetically useful reactions. 

Allylic acetates are widely used. The oxidative addition of allylic acetates to Pd(0) is reversible, and their reaction must be carried out in the presence of bases. An important improvement in 7r-allylpalladium chemistry has been achieved by the introduction of allylic carbonates. Carbonates are highly reactive. More importantly, their reactions can be carried out under neutral con-ditions[13,14]. Also reactions of allylic carbamates[14], allyl aryl ethers[6,15], and vinyl epoxides[16,17] proceed under neutral conditions without addition of bases. 

Phenylphosphole with [Os3(CO)l2] and [Os3(CO)ll(AN)] under reflux conditions gives rise to 240 (R = H) and 241 as isolable products [91JOM(408)C18]. l-Phenyl-3,4-dimethylphosphole with [Os3(CO)l2] or [Os3(CO)j (AN)lo -J (x= 1, 2) yields 242 and 243. The latter, however, experiences subsequent oxidative addition to give 240 (R = Me). Species 242 and 240 (R = Me) mutually transform into each other, the direct process induced by light and the reverse occurring in dark [91JCS(D)3381],... 

The general catalytic cycle for the coupling of aryl-alkenyl halides with alkenes is shown in Fig. 9.6. The first step in this catalytic cycle is the oxidative addition of aryl-alkenyl halides to Pd(0). The activity of the aryl-alkenyl halides still follows the order RI > ROTf > RBr > RC1. The olefin coordinates to the Pd(II) species. The coordinated olefin inserts into Pd—R bond in a syn fashion, p-Hydrogen elimination can occur only after an internal rotation around the former double bond, as it requires at least one /I-hydrogen to be oriented syn perpendicular with respect to the halopalladium residue. The subsequent syn elimination yields an alkene and a hydridopalladium halide. This process is, however, reversible, and therefore, the thermodynamically more stable (E)-alkene is generally obtained. Reductive elimination of HX from the hydridopalladium halide in the presence of a base regenerates the catalytically active Pd(0), which can reenter the catalytic cycle. The oxidative addition has frequently assumed to be the rate-determining step. 

The dominant factors reversing the conventional ds-hydroboration to the trans-hydroboration are the use of alkyne in excess of catecholborane or pinacolborane and the presence of more than 1 equiv. of EtsN. The P-hydrogen in the ris-product unexpectedly does not derive from the borane reagents because a deuterium label at the terminal carbon selectively migrates to the P-carbon (Scheme 1-5). A vinylidene complex (17) [45] generated by the oxidative addition of the terminal C-H bond to the catalyst is proposed as a key intermediate of the formal trans-hydroboration. 

The oxidative addition of (ArS) 2 to Pd(0) and coordination of 73 to the resultant Pd(II) both lower the total energy [state (C) from (A) via (B)]. Both the insertion of isocyanide into Pd-S of 78 giving state (D) and the reductive elimination of 74 from 79 affording state (E) are reversible. The equilibrium of the insertion and de-insertion of the isocyanide favors the formation of the product of the de-insertion reaction. [State (C) is lower than state (D).] Although state (C) is more stable than state (E), the short-lived Pd(0) can be trapped by (ArS)2 to give 77 [state (E) from state (E)]. 

It is not clear whether the X anion remains ligated to the palladium(II) center. For example, for acetic acid, the palladium hydride was initially postulated as being HPd(OAc)L ,377,378 but more recently as HPdL +.367 To date, none of these complexes has been characterized.367 Oxidative addition of acetic acid or formic acid to a palladium(O) complex in DMF affords a cationic palladium hydride /ruw.v-I IPd(PPh3)2(DMF)+, with an acetate or a formate counter-anion. Both reactions are reversible and involve an unfavorable equilibrium so that a large excess of acid is required for the quantitative formation of the palladium hydride complex.379 This allows us to conclude that the catalytic reactions initiated by reaction of palladium(O) and acetic acid (or formic acid) proceed via a cationic palladium hydride trans-HPdfPPtHWDMF)"1", when they are performed in DMF.379... 

The oxidative addition of hexafluoroacetone to 221 gives 222 (X = CH) in which chloromethane has been eliminated in a ring-closing step to give a product with a bridgehead phosphorus center (Scheme 28). Analogous products 223 were obtained by treatment of 221 (X = N) with hexafluoroacetone (Scheme 29) <2000ZFA412>. The oxidative addition was found to be reversible. 

Having established structural and electronic analogies between metal oxides and alkoxides of molybdenum and tungsten, the key remaining feature to be examined is the reactivity patterns of the metal-alkoxides. Metal-metal bonds provide both a source and a returning place for electrons in oxidative-addition and reductive elimination reactions. Stepwise transformations of M-M bond order, from 3 to 4 (37,38), 3 to 2 and 1 (39) have now been documented. The alkoxides M2(0R)6 (MiM) are coordinatively unsaturated, as is evident from their facile reversible reactions with donor ligands, eq. 1, and are readily oxidized in addition reactions of the type shown in equations 2 (39) and 3 (39). 

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