Hydroamination with aromatic amines

Gallium The hydroamination products ArCH(NArR )CH3 have now been obtained from the reaction of alkynes ArC=CH with aromatic amines ArNHR, catalysed by GaCl3, followed by reduction of the imine intermediates ArC(NArR )=CH2 with LiAlH4. DFT calculations suggest that the key step proceeds as a Markovnikov-type iyn-addition of GaCl3 and the amine across the C=C bond. ... 

The formation of a bis(guanidinate)-supported titanium imido complex has been achieved in different ways, two of which are illustrated in Scheme 90. The product is an effective catalyst for the hydroamination of alkynes (cf. Section V.B). It also undergoes clean exchange reactions with other aromatic amines to afford new imide complexes such as [Me2NC(NPr )2]2Ti = NC6F5. ... 

Under the same conditions, the hydroamination of acetylene with primary or secondary aromatic amines brings about the formation of dimerization-cyclization products since the generated imines or enamines, respectively, are not stable. 

Subshtuted 3-alken-l-ynes can be hydroaminated with primary or secondary aliphahc or aromatic amines at the alkynyl sites or at the alkynyl and at the alkenyl sites in the presence of Hg(ll) salts. However, the reachon is essentially stoichiometric in nature, even if the mercury compound can be recycled without apparent loss of achvity [262-264]. 

The first example of anti-Markovnikoff hydroamination of aromatic alkenes has been demonstrated with cationic rhodium complexes.170 A combination of [Rh(COD)2]+/2PPh3 in THF under reflux yields the N-H addition product as the minor species alongside that resulting from oxidative amination (Scheme 37). Hydrogenation products are also detected. 

Very recently, Genet and Michelet developed a diastereoselective reaction that took place by hydroamination of an unactivated alkene followed by a cydization process under very mild conditions. This 1,6-enyne reaction was compatible with electron-poor aromatic amines, including amines bearing chloride atoms (Equation 8.73), which is very useful for further functionalization of the substituted aniline ring [164]. 

A palladium-catalyzed three-component reaction with 2-iodobenzoyl chloride or methyl 2-iodobenzoate, allene and primary aliphatic or aromatic amines to prepare fV-substituted 4-methylene-3,4-dihydro-1 (27/)-isoquinolin-1 -ones was disclosed <02TL2601>. A synthesis of 1-substituted 1,2,3,4-tetrahydroisoquinolines via a Cp2TiMe2-catalyzed, intramolecular hydroamination/cyclization of aminoalkynes was also reported <02TL3715>. Additionally, a palladium-catalyzed one-atom ring expansion of methoxyl allenyl compounds 79 to prepare compounds 80 that can serve as precursors to isoquinolones was reported <02OL455,02SL480>. 

The diastereoselective addition of aniline to norbornene was accomplished using a catalytic amount of iridium(I). As the intermediate azametallacyclobutane 2 could be isolated its stereochemistry was determined by X-ray analysis both iridium and nitrogen occupy the exo position41. However, the scope of the amination method, with respect to the nature of the amine and the structure of the alkene, was not determined. Conversely, the analogous rhodium(I)-cat-alyzed reactions of norbornene and aromatic amines gave mixtures of hydroamination and hydroarylation products106. 

Che has reported the tandem hydroamination/hydroarylation of aromatic amines wirh terminal alkynes to form dihydroquinolines in which 1 equiv of aniline combines with 2 equiv of alkyne [23]. For example, reaction of 3-methoxyanilme with pheny-lacetylene (5 equiv) and a catalytic 1 1 mixture of the gold(I) N-heterocydic carbene complex (IPr)AuCl (IPr= l,3-bis(2,6-diisopropylphenyl)imidazol-2-ylidine) and AgOTf at 150 °C under microwave irradiation led to isolation of dihydroquinoline 21 in 82 % yield (Eq. (11.15)). Alternatively, reaction of o-acetylaniline with pheny-lacetylene catalyzed by a mixture of (IPr)AuCl and AgOTf at 150 °C led to isolation of the quinoline derivative 22 in 93% yield via incorporation of a single equivalent of alkyne (Eq. (11.16)). Arcadi has reported the gold(IlI)-catalyzed hydroamination/ hydroarylation of 2-alkynylanilines with a,p-enones to form C3-alkyl indoles [24]. As an example of this transformation, treatment of 2-(phenylethynyl)aniline with 4-phenyl-3-buten-2-one and a catalytic amount of sodium tetrachloroaurate dihydrate in ethanol at 30°C formed 1,2,3-trisubstituted indole 23 in 88% yield (Eq. (11.17)). 

Furthermore, this follow-up study also illustrated the broad applicability of DMCs for the hydroamination of various substrate molecules [37]. Zn-Co-DMCs could catalyze the hydroamination reaction of both aromatic and aliphatic alkynes with aromatic as well as aliphatic amines, a rare trait in heterogeneous hydroamination catalysts. 

The hydroamination of phenylacetylene with primary or secondary aromatic amines is also catalyzed by Tl(OAc)3 to give imines or enamines, respectively, in low to good yields (10-89%) with TOE up to 6 h [261]. 

A number of actinide complexes have been investigated with respect to their catalytic activity in the intermolecular hydroamination of terminal alkynes with primary ahphatic and aromatic amines [98, 206-209]. Secondary amines generally do not react and the reaction is believed to proceed via an metal-imido species similar to that of group 4 metal complexes. The reaction of Cp 2UMc2 with sterically less-demanding aliphatic amines leads exclusively to the anti-Markovnikov adduct in form of the -imine (31) [207] however, sterically more demanding amines, e.g., t-BuNH2, result in exclusive alkyne dimerization. The ferrocene-diamido uranium complex 12 (Fig. 4) catalyzes the addition of aromatic amines very efficiently (32) [98]. 

The hydroamination of alkynes with primary and secondary ahphatic amines necessitates the use of higher amounts of catalyst (17%) and higher temperatures, and TOFs are low (<1 h ) [260]. With ahphatic and aromatic terminal alkynes and a 5-fold excess of primary aliphahc amines, the products are the corresponding imines (40-78% yield, TOF up to 0.3 h ). In contrast to the CujClj-catalyzed reaction of phenylacetylene and secondary ahphatic amines (Scheme 4-12), the HgClj-catalyzed reachon is fully regioselechve for the Markovnikov hydroamination products which do not evolve under the reachon condihons (Eq. 4.66) [260]. 

Schafer found that the bulky bis(amidate) complex is an effective catalyst for intermolecular hydroamination of terminal alkyl alkynes with alkylamines, giving exclusively the anti-Markovnikov aldimine product [309]. The same titanium complexes can also be utilized in the hydroamination of substituted allenes in good yields (Scheme 14.132). Under the catalysis of an imidotitanium complex, the highly strained methylenecyclopropane can undergo hydroamination reaction with either aromatic or aliphatic amines, to give ring-opened imine products in good to excellent yields and chemoselectivities [310]. 

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