Hydroamination lanthanide amides

Lanthanide complexes also catalyze the hydroamination of 13-dienes. The lanthanide catalysts originally developed for the intramolecular hydroamination of aminoalkenes are particularly active for the intramolecular additions of alkyl amines to dienes. The scope of this process is broad an illustrative example showing the high diastereoselectiv-ity of the cyclization of a chiral amine is shown in Equation 16.82. These reactions occur by insertion of the diene into a lanthanide-amide intermediate to form an allyl-metal intermediate. 

Qrganolanthanides such as metallocene or halfmetallocene andnomnetallocene lanthanide amides, alkylides, and hydrides are highly efficient catalysts for the intramolecular hydroamination/cyclization of a wide range of substrates such as aminoalkenes (Scheme 2), aminoalkynes, aminoal-lenes, and aminodienes. ... 

In 2003, Livinghouse et al. also reported that chelating bis(thiophosphonic amidates) complexes of lanthanide metals, such as yttrium or neodymium, were able to catalyse intramolecular alkene hydroaminations. These complexes were prepared by attachment of the appropriate ligands to the metals by direct metalation with Ln[N(TMS)2]3- When applied to the cyclisation of 2-amino-5-hexene, these catalysts led to the formation of the corresponding pyrrolidine as a mixture of two diastereomers in almost quantitative yields and diastereos-electivities of up to 88% de (Scheme 10.81). 

A different mechanism again is involved in the hydroamination reaction catalyzed by lanthanide complexes, Cpff.nR which is applied to the cyclization of unsaturated amines. The mechanism involves the formation of a metal amide species from both the catalysts (by different routes), followed by the turnover —limiting intramolecular insertion of the alkene to give a cr-complex, from which the decomplexed cyclic amine is obtained after reaction with a second molecule of the unsaturated amine19,20,107. 

To catalyze the direct hydroamination of olefins according to eq. (1) two basic approaches have been employed involving primarily the activation either of the amine or of the olefin. One possible way to activate the amine for catalysis is the transformation to the much stronger nucleophilic amide ion by deprotonation. Thus, the amides of strongly electropositive metals, such as alkali metals, alkaline earth metals, or lanthanides, are able to react with the C-C double bond under... 

The scope of the lanthanide-mediated, intramolecular amination/cyclization reaction has been determined for the formation of substituted quinolizidines, indolizidines, and pyrrolizidines,1046 as well as tricyclic and tetracyclic aromatic nitrogen heterocycles.1047 The amide derivative OT ro-[ethylene-bis(indenyl)]ytterbium(m) bis(trimethyl-silyl)amide catalyzes the hydroamination of primary olefins in excellent yields.701 A facile intramolecular hydroamination process catalyzed by [(C5H4SiMe3)2Nd(/r-Me)]2 has also been reported. The lanthanide-catalyzed hydroamination enables a rapid access to 10,1 l-dihydro-5//-dibenzo[tf,rf]cyclohepten-5,10-imines (Scheme 283).1048... 

Examples of the insertions of alkenes or alk5mes into metal-amido bonds are also rare. Examples of the insertions of alkenes into tihe M-N bonds of isolated amido complexes include the reaction of a rhodium anilide complex with alkenes to form imines witii kinetic behavior that is consistent with migratory insertion,and the formal insertion of the strongly electrophilic acrylonitrile into a platinum anilide. Additional examples include reactions of a lanthanide-amido complex generated in situ, a catalytic carboamination process in which the stereochemistry implies insertions of olefins into amides, and a catalytic hydroamination that appears to occur through an aminoalkyl complex generated by S3m addition of the iridium and amido groups across the C=C bond of norbomene. 

The hydroamination of olefins has been shown to occur by the sequence of oxidative addition, migratory insertion, and reductive elimination in only one case. Because amines are nucleophilic, pathways are available for the additions of amines to olefins and alkynes that are unavailable for the additions of HCN, silanes, and boranes. For example, hydroaminations catalyzed by late transition metals are thought to occur in many cases by nucleophilic attack on coordinated alkenes and alkynes or by nucleophilic attack on ir-allyl, iT-benzyl, or TT-arene complexes. Hydroaminations catalyzed by lanthanide and actinide complexes occur by insertion of an olefin into a metal-amide bond. Finally, hydroamination catalyzed by dP group 4 metals have been shown to occur through imido complexes. In this case, a [2+2] cycloaddition forms the C-N bond, and protonolysis of the resulting metallacycle releases the organic product. 

Metal-catalyzed asymmetric hydroamination/cyclization reaction (for Lanthanide complexes) is believed to proceed through catalytic pathways as shown by Marks and co-workers. It is speculated that metal amide complex A is the starting point of the catalytic cycle (Scheme 39.2). 

Amine activatitMi pathway has been well studied in catalysis by lanthanides, early transition metals, and alkali metals. In metal amide chemistry of late transition metals, there are mainly two pathways to synthesize metal amide complexes applicable under hydroamination conditions [54], One is oxidative addition of amines to produce a metal amide species bearing hydride (Scheme 8a). The other gives a metal amide species by deprotonation of an amine metal intermediate derived from the coordination of amines to metal center, and it often occurs as ammonium salt elimination by the second amine molecule (Scheme 8b). Although the latter type of amido metal species is rather limited in hydroamination by late transition metals, it is often proposed in the mechanism of palladium-catalyzed oxidative amination reaction, which terminates the catalytic cycle by p-hydride elimination [26]. Hydroamination through aminometallation with metal amide species demands at least two coordination sites on metal, one for amine coordination and another for C-C multiple bond coordination. Accordingly, there is a marked difference between the hydroamination via C-C multiple bond activation, which demands one coordination site on metal, and via amine activation. 

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