Aminoalkenes catalytic hydroamination/cyclization

Ge, S.Z., Meetsma, A., and Hessen, B. (2008) Neutral and cationic rare earth metal alkyl and benzyl compounds with the l,4,6-trimethyl-6-pyrrolidin-l-yl-l,4-diazepane Ugand and their performance in the catalytic hydroamination cyclization of aminoalkenes. Organometallics, 27, 5339. 

Scheme 4 Catalytic hydroamination/cyclization of an aminoalkene with an internal double bond [104,125]...

Scheme 11.10 Catalytic hydroamination/cyclization of aminoalkenes using chiral amino thiophenolate yttrium complexes [61].

Scheme 11.11 Catalytic hydroamination/cyclization of aminoalkenes using 3,3 bisftrisarylsih substituted binaphtholate rare earth metal complexes [52].

Although efficient for the intramolecular hydroamination/cyclization (abbreviated IH below) of aminoalkenes (see below), organolanthanides exhibit a much lower catalytic activity for the intermolecular hydroamination of aUcenes, as exemplified by the reaction of n-PrNH2 with 1-pentene catalyzed by a neodymium complex (Eq. 4.17) [127]. 

Intramolecular hydroamination/cyclization, the addition of an N-H bond across an intramolecular carbon-carbon unsaturated bond, offers an efficient, atom economical route to nitrogen-containing heterocyclic molecules (Equation 8.37). Numerous organolanthanide complexes were found to be efficient catalysts for this transformation [124, 125]. The real active intermediates are organolanthanide amides, which are formed by the rapid protonolysis reactions of precatalysts with amine substrates. The proposed catalytic cycle of hydroamination/cyclization of aminoalkenes is presented in Figure 8.37 [124]. 

Figure 837 The proposed catalytic cycle of hydroamination/cyclization of aminoalkene.

Pioneering experimental findings by Marks and coworkers [97,103,114] followed by theoretical analysis [109] allowed elucidation of the mechanism of aminoalkene hydroamination/cyclization (Fig. 13). The reaction is considered to proceed through a rare-earth metal amido species, which is formed upon protonolysis of a rare-earth metal amido or alkyl bond. As discussed in the previous section, the first step of the catalytic cycle involves insertion of the alkene into the rare-earth metal amido bond with a seven-membered chair-like transition state (for n = 1). The roughly thermoneutral [103,109] insertion step is considered to be rate-determining, giving rise of a zero-order rate dependence on substrate concentration and first-order rate dependence on catalyst concentration. 

Fig. 13 Simplified catalytic cycle for aminoalkene hydroamination/cyclization [103,109]...

Another interesting aspect is the metal size effect. In general, increasing ionic radii correlate with enhanced catalytic activity in hydroamination/cyclization of aminoalkenes [27,103,114], However, a different tiend is observed for phosphinoalkenes. Here, the mid-sized yttrium shows the highest reactivity, followed by lutetium and samarium, while the largest rare-earth metal, lanthanum, is the least active catalyst system [179],... 

The catalytic activity of the ytterbium complex 170 was investigated in the hydroamination/cyclization reactions of aminoalkenes. Various nonactivated aminoalkenes were used as substrates (Scheme 43). The reaction scope is limited to five-membered ring formation. The aminoalkenes bearing bulky geminal substituents in P-position to the amino group are more reactive and could be... 

Rare earth metal complexes witii stericaUy demanding tris(aryl)silyl-substituted binaphtholate ligands efficiently catalyze asymmetric hydroamination/cyclization of aminoalkenes and the kinetic resolution of a-substituted aminopentenes. The catalytic activities are comparable to... 

Scheme 17 Catalytic asymmetric hydroamination/cyclization of aminoalkenes...

Neutral group 4 metal complexes appear to possess a relatively broad scope for catalytic hydroaminations. They have been employed for the intramolecular hydroamination of alkynes [2], allenes [3], and alkenes [4] as well as the inter-molecular hydroaminations of alkynes [5] and allenes [6]. Primary aryl- and alkylamines readily react, but secondary amines have posed a greater challenge for this type of transformation with neutral catalysts [7]. For the reactions of the latter, cationic Zr and Ti complexes have been employed in intramolecular cyclizations of aminoalkenes [8]. Very recent work suggests that substrates that are difficult to hydroaminate may favor hydroaminoalkylations instead (Scheme 13.2) [9]. 

The intramolecular hydroamination reaction of aminoalkenes and other substrates involves two key steps in the catalytic cycle. Although the insertion step is generally perceived as the rate-determining step of the process, this may not be true for aU substrate classes. The hydroamination/cyclization of aminoalkenes differs significantly from reactions involving aminoalkynes, aminoaUenes, and conjugated aminodienes from a thermodynamic point of view. The alkene insertion step of the... 

Only a limited number of organoactinide catalysts have been investigated for the hydroamination/cyclization of aminoalkenes (Fig. 4, Table 2) [55, 96-98]. The constrained geometry catalysts 11-An (An = Th, U) show high activity comparable to the corresponding rare earth metal complexes and can be applied for a broad range of substrates [55, 96, 97]. The ferrocene-diamido uranium complex 12 was also catalytically active for aminoalkene cyclization, but at a somewhat reduced rate [98]. Mechanistic studies suggest that the actinide-catalyzed reaction occurs via a lanthanide-like metal-amido insertion mechanism and not via an imido mechanism (as proposed for alkyne hydroaminations), because also secondary aminoalkenes can be cyclized [55, 98]. 

Intramolecular addition of amine N-H bonds to carbon-carbon multiple bonds would afford nitrogen heterocycles. To realize catalytic cyclization of a,co-aminoalkenes or aminoalkynes, various catalytic systems have been developed especially with early transition metals such as titanium, zirconium, lanthanide metals, and actinide metals [ 12], Late-transition-metal catalysis based on Ni, Pd, and Rh has also proved to be efficient [ 12], Recently, the ruthenium-catalyzed intramolecular hydroamination of aminoalkynes 15 was reported to afford 5-7-membered ring products 16 in various yields (Eq. 6) [13]. Among... 

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