Aryl bromides arylamine synthesis

Aryl iodides, bromides, chlorides, triflates and some tosylates are used for the arylamine synthesis. Secondary (dialkyl, alicyclic, alkyl-aryl, and diarylamines) and primary amines (alkyl and arylamines) participate in the reaction with different reactivity. In general, more basic and less bulky amines react faster. 

With the development of Buchwald-Hartwig amination reactions, the amine component of these indoles can also be introduced into these precursors via palladium catalysis [8]. As shown by Ackermann, this can be coupled with aryl halide alkynylation and cyclization to provide a one-pot, three-component synthesis of substituted indoles (Scheme 6.6) [9]. In this case, simple ortho-dihaloarene derivatives S were employed as starting materials, with Sonogashira coupling occurring at the more activated aryl-iodide bond, followed by selective coupling of various alkyl or arylamines. Alternatively, Zhao has recently demonstrated that amination can be performed on both bromoalkyne 6, followed by the aryl-bromide bond, to provide a route to 2-amidoindoles (Scheme 6.7) [10]. 

Transition Metal-Catalyzed Coupling Reactions Synthesis of Aryl Amines. LHMDS was first used as a base to de-protonate alkylamines in the palladium-catalyzed synthesis of arylamines. This base is mild enough such that the alkyl-amide is generated at the transition metal center. Earlier examples reported that the reaction of an aryl bromide with cyclo-hexylamine and LHMDS in the presence of 5 mol % of (tri-o-tolylphosphine)2PdCl2 in toluene at 100 °C produced the desired arylamine in 89% yield after 2 h (eq 19). ... 

Discrete copper compounds can also be used as catalysts for the synthesis of arylamines (Scheme 3.52) [58]. Venkataraman used a neocuproine-ligated copper(I) species to promote the coupling of aryl halides with secondary amines. A practical advantage to this chemistry was that only air-stable materials were needed to construct the catalyst needed for the cross-coupling. A base was needed to promote the reaction, and potassium tert-butoxide was found to be more effective in the cross-coupling than other common bases including potassium phosphate, sodium methoxide, or cesium carbonate. Curiously, cesium carbonate was not as active in this chemistry, but it was quite effective in the preparation of diaryl ethers. Several aryl halides were screened for activity, and aryl bromides and iodides afforded moderate to good yields of the arylamines. It should be noted that an electron-neutral aryl chloride was converted into the triarylamine, albeit in lower yield (49%). 

More recently, Polish chemists have reported a synthesis of both aryl and aliphatic secondary nitramines by treating amine substrates with ethyl magnesium bromide followed by reaction with n-butyl nitrate (Equation 5.8). This method, which uses nonpolar solvents like hexane or benzene, has been used to synthesize aliphatic secondary nitramines, and At-nitro-A-methylanilines which otherwise undergo facile Bamberger rearrangement in the presence of acid. The direct nitration of At-unsubstituted arylamines usually requires the presence of an electron-withdrawing group. Reactions are retarded and yields are low for sterically hindered amines. 

The difference in reactivity between the aryl iodide and bromide was exploited by Sulikowski in the synthesis of a mytomycin skeleton [69]. The desired arylamine was prepared in 66% yield with exclusive reaction at the iodide, Eq.(39). 

In addition to reactions initiated with copper metal, reactions have been conducted with copper salts, such as copper oxides, alloys and coordination complexes. Reactions with many bases in several polar solvents have also been explored. Diphenylamine and o-bromonitrobenzene couple with stoichiometric amounts of copper(I) oxide and copper(I) bromide in DMA (equation 59)234. The synthesis of triaryl amines from aryl iodides and arylamines in one-pot proceeds in the presence of Cul and potassium tart-butoxide at 135 °C235. The highest yields were obtained with aryl iodides and electron-rich arylamines. 

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