Amines, metal catalyzed reaction with aryl halides

Elimination-addition reactions of aryl halides with alkali-metal amides are discussed in Section 14-6C high-temperature copper-catalyzed amination, also effective, usually does not lead to rearrangement. 

The transition metal catalyzed synthesis of arylamines by the reaction of aryl halides or tri-flates with primary or secondary amines has become a valuable synthetic tool for many applications. This process forms monoalkyl or dialkyl anilines, mixed diarylamines or mixed triarylamines, as well as N-arylimines, carbamates, hydrazones, amides, and tosylamides. The mechanism of the process involves several new organometallic reactions. For example, the C-N bond is formed by reductive elimination of amine, and the metal amido complexes that undergo reductive elimination are formed in the catalytic cycle in some cases by N-H activation. Side products are formed by / -hydrogen elimination from amides, examples of which have recently been observed directly. An overview that covers the development of synthetic methods to form arylamines by this palladium-catalyzed chemistry is presented. In addition to the synthetic information, a description of the pertinent mechanistic data on the overall catalytic cycle, on each elementary reaction that comprises the catalytic cycle, and on competing side reactions is presented. The review covers manuscripts that appeared in press before June 1, 2001. This chapter is based on a review covering the literature up to September 1, 1999. However, roughly one-hundred papers on this topic have appeared since that time, requiring an updated review. 

Thus, the transition metal catalyzed arylation reactions of amines and alcohols would constitute powerful tools for synthetic chemists. We have been developing practical procedures for the palladium-catalyzed arylation of amines and alcohols with aryl halides or sulfonates. During the course of our investigations [9] as well as those of John Hartwig and co-workers [10] the substrate scope of these transformations has been incrementally expanded. With each cycle of this catalyst improvement process, advances in mechanistic understanding and ligand design have also been made. 

C.iii.c. Preparation of Small Molecules for Materials Science. Pd-catalyzed amination has also been used to prepare small molecules that are useful as hole-transport materials, selective metal-cation detection systems, and dyestuffs. As mentioned briefly in the section on reacting diarylamines with aryl halides, Marder and co-workers used palladium chemistry to form triarylamines, which are useful as hole-transport layers. Reactions of primary arylamines with aryl halides using DPPF-hgated palladium as catalyst allows for the selective addition of one aryl halide, followed by the addition of a second aryl halide to form mixed triarylamines, as shown in Eq. 42. This procedure has been used to generate unsymmetrical triarylamines that are analogs of TPD, as shown in Eq. 43. hi addition, they have used aminoferrocene as a substrate to conduct diarylations to form N, A-diarylaminoferrocenes. ... 

Metal catalyzed formation of an arylamine by a reaction of aryl halide of triflate with primary or secondary amine ... 

Aryl- and heteroaryl halides can undergo thermal or transition metal catalyzed substitution reactions with amines. These reactions proceed on insoluble supports under conditions similar to those used in solution. Not only halides, but also thiolates [76], nitro groups [76], sulfinates [77,78], and alcoholates [79] can serve as leaving groups for aromatic nucleophilic substitution. 

The mechanism of the amines or alcohols arylation catalyzed by nickel(II) complexes has not been elucidated until now (refs. 7, 17), even though the arylation of nucleophiles catalyzed by nickel(0) complexes is better understood. In this last case it is generally admitted that the reaction proceeds by an oxidative addition step, followed by a nucleophilic substitution, and then a reductive elimination of the arylation product (Scheme 4). According to the work of Kochi (ref. 18), the oxidative addition of the haloarene on a nickel(O) complex takes place through a monoelectronic transfer from the metal to the aryl halide with simultaneous formation of a nickel(I) intermediate, the actual catalyst of the reaction (ref. 6). 

Various palladium species catalyze the reaction, and a common procedure is to start with Pd(OAc>2, PPhj, NaOAc and sometimes NEtj. The reaction generally is done at elevated temperatures (100-150 C) in a polar solvent, such as dimethylacetamide or dimethyformamide. The reaction usually proceeds with formation of at least some Pd metal. The standard reaction sequence involves first reduction of Pd(II), possibly by phosphine or amine, to a ligated Pd(0) species, often represented as PdLj. The latter is proposed to undergo oxidative addition with the aryl halide, and the resulting Pd"(Ar)(X)(L)2 species loses an L and coordinates the olefin. Then, the aryl group inserts into the Pd—olefrn bond. This is followed by p-hydride elimination, possibly assisted by base, liberation of the product and re-coordination of L to regenerate the catalyst. Further details can be found in recent reviews by Crisp, Beletskaya and Cheprakov and Amatore and Jutland. It should be noted that the electrochemical studies of the latter workers indicate that the Pd(0) is present as an anionic complex, such as Pd(L)2(OAc)", and that the oxidative addition gives a 5-coordinate Pd(II) species, such as Pd(Ar)(X)(L)2(OAc)". 

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