Substitution, allylic nucleophilic aromatic

Monoalkylation of a-isocyano esters by using tert-butyl isocyano acetate (R = fBu) has been reported by Schollkopf [28, 33]. Besides successful examples using primary halides, 2-iodopropane has been reported to produce the a-alkylated product (1) as well by this method (KOfBu in THF). In the years 1987-1991, Ito reported several methods for the monoalkylation of isocyano esters, including the Michael reaction under TBAF catalysis as described earlier [31], Claisen rearrangements [34], and asymmetric Pd-catalyzed allylation [35]. Finally, Zhu recently reported the first example of the introduction of an aromatic substituent by means of a nucleophilic aromatic substitution (Cs0H-H20, MeCN, 0°C) in the synthesis of methyl ot-isocyano p-nitrophenylacetate [36]. 

The chemistry involved in nucleophilic aromatic substitution is well reflected in the reactions of a variety of nucleophiles with methyl penta-fluorophenyl ether (Ingemann et al 1982a). For most of the nucleophiles such as alkoxide, thiolate, enolate and (un)substituted allyl anions, the dominant reaction channel is the attack upon the fluoro-substituted carbon atoms, as is the case for OH-. The latter ion reacts approximately 75% by attack upon the fluoro-substituted carbon atoms and the remaining 25% by Sn2 (20%) and ipso (5%) substitution as summarized in (41). In the attack upon the fluorinated carbon atoms, the interesting observation is made that a F- ion is displaced via an anionic o-complex to form a F- ion/molecule complex, which is not observed to dissociate into F- as a free ionic product. 

Indications of the occurrence of cycloaddition were first obtained from reactions of specifically deuterated allyl anions with tetrafluoroethylene. Assuming that no hydrogen/deuterium exchange occurs in the collision complex as shown for the allyl anions themselves (Dawson el al., 1979a), the results obtained (Nibbering, 1979) may be interpreted as indicating that 65% of the allyl anions react by a linear addition (51), 20% by a [2 + 2] atom cycloaddition (52) and 15% by a [2 + 3] atom cycloaddition. (53). It should be noted here that the precise mechanistic details of the losses of HF molecules from the collision complexes in eqns (51)—(53) are not known. However, in view of the nucleophilic aromatic substitution discussed in the previous section, it is quite likely that they occur in a stepwise fashion in which complexes solvated by fluoride anions play a role. 

A particularly interesting combination of allyl ligand structure and the high reactivity toward aryl halides leads to the synthesis equivalent of nucleophilic aromatic substitution by enolate anions, but under completely different conditions (Scheme 51). In this example, the 2-methoxyallyl ligand is equivalent to an acetone enolate anion, but reacts with very different functional group compatibility (no polar... 

Dioxanes have been synthesized from l-O-allyl-l,2-diols by radical addition of per-fluoroalkyl iodides and subsequent nucleophilic cyclization.561 With sodium hydride, elimination occurs from iodides such as 1.3 other bases also give unsatisfactory results, whereas N-bromosuccinimide seems to be the reagent of choice for the cyclization to 1,4-dioxane 14. Similar results arc obtained with dibromodimethylhydantoin.561 Dihydrobenzofurans are synthesized by cyclodehydration utilizing the Vilsmeier reagent (chloromethylene)dimethylam-monium chloride is most practical.562 Nucleophilic aromatic substitution reactions with catechol derivatives also give the six-membered heterocycles.563 564 1.4-Dioxan-2-ones arc pre-... 

Star-shaped molecules containing cationic arene complexes of iron and ruthenium have been reported by Astruc and co-workers.298 Utilizing the activating nature of the cyclopentadienyliron moiety on the complexed arene, 260 was converted into 262 via bromobenzylation. The photolysis of 262 gave 263, which was subsequently reacted with 264 to give the hexametallic complex 265. Further nucleophilic aromatic substitution reactions with phenol 266 gave the allyl-substituted complex 267 (Scheme 2.70). 

C-allylation of PhO" Na with H2C=CHCH2C1 in a variety of solvents in the presence of different crown ethers is most effective in each case when using poly(vinylbenzo-15-crown-5)polyether. Only in the presence of the crown ethers 15-crown-5 and 18-crown-6 are the anions in potassium phthalimide and sodium saccharinate, respectively, sufficiently activated to bring about nucleophilic aromatic substitution of the 4-fluorine in pentafluoropyridine. The formation of 2,4-dinitrophenol, in addition to the expected ether, from 2,4-dinitrochlorobenzene and potassium 2-propoxide in 2-propanol-benzene (1 1), in the presence of dicyclohexyl-18-crown-6 polyether, has been accounted for on the basis of a nucleophile-radical reaction (5rn1)/ ... 

In Sjj2 reactions of aUg l halides, the order of reactivity is RI > RBr > RCl > RF. Alkyl iodides are considerably more reactive than allyl fluorides, often by factors as great as 10 . All l-halo-2,4-dinitrobenzenes, however, react at approximately the same rate in nucleophilic aromatic substitutions. Account for this difference in relative reactivities. 

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