Alkyl palladium nucleophilic displacement

Oxidative Addition of Alkyl Halides to Palladium(0). The stereochemistry of the oxidative addition (31) of alkyl halides to the transition metals of group VIII can provide information as to which of the many possible mechanisms are operative. The addition of alkyl halides to d8-iridium complexes has been reported to proceed with retention (32), inversion (33), and racemization (34, 35) via a free radical mechanism at the asymmetric carbon center. The kinetics of this reaction are consistent with nucleophilic displacement by iridium on carbon (36). Oxi-... 

Xlld does not involve the chiral center, so if the reaction takes place by this pathway, the migration of the alkyl group from sulfur to palladium (with the concomitant or subsequent loss of sulfur dioxide) must take place with inversion of configuration at carbon. Inversion of configuration at carbon has been observed in the reverse-type reaction, the sulfur dioxide insertion into a carbon-iron sigma bond (49). Nucleophilic displacement at carbon in compounds of type Xld is unusually difficult, so the reaction via the sulfite intermediate Xlld would appear to be more likely. Conversion of the tosylate of l-phenyl-2,2,2-trifluoroethanol to the corresponding chloride, a reaction which takes place in the presence of tetra- (n-butyl) ajnmonium chloride with inversion of configuration at carbon, requires 100°C for 24 hrs in dimethylsulfoxide. 

To expand the diversity of their libraries Brill et al.16 also modified various heterocycles by alkylation, acylation, or metal-mediated coupling reaction prior to resin capture. A remaining chloro substituent was still available for nucleophilic displacement or a palladium-mediated coupling reaction with anilines, phenols, and boronic acids on solid phase [see Fig. 10 for the preparation of purine derivative (62)]. 

The palladium-mediated substitution of allylic substrates proceeds in two independent steps. For stabilized carbanions both oxidative addition and the nucleophilic displacement occur with inversion of configuration. Thus, overall retention results, in contrast to the corresponding reactions of nonstabilized carbanions as nucleophiles (see Section D.l. 5.6.3.). The steric course of the reaction is proved by the absence of racemization in Lhe conversion of chiral substrates into chiral alkylated products. Furthermore, chiral n-allylpalladium complexes formed with inversion from stoichiometric reactions of palladium(O) with allyl substrates have been isolated. Coupling of these stereodefined complexes with soft carbanions yields the chiral alkylated products, again with inversion of configuration. 

As alluded to above, this version of the Jt-allyl palladium reaction uses an allylic acetate or chloride. The use of the acetate is more common because acetate is a much weaker nucleophile than chloride. When it involves a substrate where diastereomeric products can result, the stereochemistry of the nucleophilic displacement is an important issue. Palladium assisted alkylation proceeds with net retention of configuration of the acetate or chloride, as seen in the conversion of 375 to 376.223e,f... 

Figure 4.2 Representative pathways for nucleophilic displacement of palladium from alkyl-palladium compounds under C-Y bond formation (relative stereochemistry for the C X bond may be syn or anti, depending on the previous pathway, see Figure 4.1.

Neither the palladium nor nickel catalyst described will promote the carbonylation of saturated aliphatic halides as noted above. However, this reaction can be catalyzed with cobalt (17) or iron (77) and probably with manganese (18) carbonyl anion salts. These carbonyl anions are strongly nucleophilic species and readily displace halide or other good leaving groups from primary or secondary positions giving alkyl metal carbonyl complexes. 

AUylic alkylations. This complex in combination with 2,2 -bipyridyl (bpy) catalyzes nucleophilic alkylation of allylic acetates and carbonates, but is less active than molybdenum or palladium catalysts. The displacement occurs with retention of configuration, as with Mo and Pd catalysts. However, alkylation occurs almost entirely at the more substituted end of the allylic group, regardless of the nucleophile. 

In addition to the most important 1,2-difunctionalization assisted or catalyzed by palladium(II) complexes, a catalytic 1,1-arylamination process of alkenes, applied to the construction of nitrogen heterocycles from 4-pentenylamides, was realized29,30. The mechanism involves the formation of arylpalladium chloride from alkyl(aryl)stannanes, the addition to the alkene, the isomerization of the adduct to the more stable benzylic palladium complex, and the displacement of palladium by an internal nitrogen nucleophile. In the presence of a substituent, mixtures of diastereomers were generally obtained. 

A better method for preparing primary amines is to use the azide synthesis, in which azide ion, is used for 8 2 displacement of a halide ion from a primary or secondary alkyl halide to give an alkyl azide, RNj. Since alkyl azides are not nucleophilic, overalkylation can t occur. Reduction of the alkyl azide, either by catalytic hydrogenation over a palladium catalyst or by reaction with LiAlH4, leads to the desired primary amine. Although the method works well, low-molecular-weight alkyl azides are explosive and must be handled carefully. 

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