Hydroamination, of alkenes

Hydroaminations of alkenes have proven to be more challenging to develop than other hydroamination reactions, although some of the first hydroaminations were additions to alkenes. In 1971 Coulson reported the addition of secondary amines to ethylene catalyzed by RhClj. Additions of amides to ethylene and propylene have been published more recently by Widenhoefer, as shown in Equation 16.57, and the addition of aniline to norbomene was published by Milstein and Casakiuovo. Although the turnover numbers for the addition of aniline to norbomene were low, several important mechanistic findings resulted from this work were presented in Chapter 9 and are reviewed in Section 16.5.3.3. Additions of amines to ethylene, propylene, and norbomene are less complicated than additions to higher olefins because these alkenes cannot undergo isomerization to a less reactive internal olefin. Nevertheless, Brunet has reported additions of arylamines to ethylene and hexene catalyzed by platinum halides with acid additive in anionic liquid (Equation 16.58).  

Intermolecular additions of primary amines to alkenes have also been reported using lanthanide catalysts. These reactions, although slow, do occur to high conversion. Similar to hydroaminations catalyzed by late transition metal complexes, these reactions form the products from Markovnikov addition of the N-H bond across the olefin. One example of such a reaction is shown in Equation 16.59.  

More examples of intramolecular additions of the N-H bonds of amines and related compounds to alkenes have been reported. The most active catalysts for these cycliza-tions contain lanthanide and group 4 metals. However, complexes of calcium have 

The bulk of the studies on intramolecular hydroamination of alkenes catalyzed by lanthanide complexes have been conducted using lanthanocene complexes or half-sandwich lanthanide complexes. The prototypical cyclizations of aminoalkenes to form five- and six-membered rings are shown in Equation 16.61. These reactions occur with exclusive Markovnikov selectivity. These reactions have also been conducted using arylamines, as shown in Equation 16.62. The intramolecular reactions of amines catalyzed by certain lanthanide complexes occur with 1,1- and 1,2-disubstituted olefins (Equation 16.63), although such reactions require high temperatures. 

These intramolecular hydroaminations lead to the formation of chiral products. Thus, several studies have been devoted to developing ligands for enantioselective, intramolecular hydroaminations of olefins catalyzed by lanthanide complexes. ° Selectivities of these reactions with chiral cyclopentadienyl derivatives have been modest. Selectivities have been higher with catalysts containing non-cyclopentadienyl ligands. Some of tlie most selective catalysts are the yttrium complexes of the bis(thiolate) ligands reported by Livinghouse, the scandium and lutetium complexes of 33 -disubstituted binaphtholates reported by Hultzsch, and the BINAM-based bisamidates of Schafer.- A representative cyclization catalyzed by a member of each of these classes of catalyst are shown in Equation 16.64. 

The iridium complex 29, bearing a pincer ligand, was an efScient catalyst for the hydroamination/cyclization of secondary amines as shown in Equation (8.18). Remarkably, both Rh and Ir catalysts were found to be air and water stable, and no appreciable loss of catalytic activity was observed when carrying out the reaction in water as solvent. For example, the desired reaction product was observed in more than 98% yield (as observed by m NMR) using catalyst 

The authors examined the scope of the system and found that the cyclized products were selectively formed in high yields. In contrast, primary amines were not converted into the corresponding N-heterocycles but gave the internal alkene isomer as the only detectible product. 

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Scheme 2.16 Gold-catalysed intramolecular hydroamination of alkenes...

Kovacs, G., Ujaque, G. and Lledos, A. (2008) The Reaction Mechanism of the Hydroamination of Alkenes Catalyzed by Gold(I)-Phosphine The Role of the Counterion and the N-Nucleophile Substituents in the Proton-Transfer Step. Journal of the American Chemical Society, 130, 853-864. 

Hydroaminomethylahon of alkenes [path (c)j wiU not be considered [12]. This review deals exclusively with the hydroaminahon reaction [path (d)], i.e. the direct addition of the N-H bond of NH3 or amines across unsaturated carbon-carbon bonds. It is devoted to the state of the art for the catalytic hydroamination of alkenes and styrenes but also of alkynes, 1,3-dienes and allenes, with no mention of activated substrates (such as Michael acceptors) for which the hydroamination occurs without catalysts. Similarly, the reachon of the N-H bond of amine derivatives such as carboxamides, tosylamides, ureas, etc. will not be considered. 

The hydroamination of alkenes has been performed in the presence of heterogeneous acidic catalysts such as zeolites, amorphous aluminosilicates, phosphates, mesoporous oxides, pillared interlayered clays (PILCs), amorphous oxides, acid-treated sheet silicates or NafioN-H resins. They can be used either under batch conditions or in continuous operation at high temperature (above 200°C) under high pressure (above 100 bar). 

Although zirconium bisamides Cp2Zr(NHAr)2 do not catalyze the hydroamination of alkenes (see above), they are catalyst precursors for the hydroamination of the more reactive double bond of allenes to give the anti-Markovnikov addition product (Eq. 4.96) [126]. 

The design of a general and efficient process for the hydroamination of alkenes would be a very important (economic) breakthrough for the production of amines. A... 

Due to its marked atom economy, the intramolecular hydroamination of alkenes represents an attractive process for the catalytic synthesis of nitrogen-containing organic compounds. Moreover, the nitrogen heterocycles obtained by hydroamination/cyclisation processes are frequently found in numerous pharmacologically active products. The pioneering work in this area was reported by Marks et al. who have used lanthanocenes to perform hydroamination/cyclisation reactions in 1992. These reactions can be performed in an intermolecular fashion and transition metals are by far the more efficient catalysts for promotion of these transformations via activation of the... 

Hydroamination of Alkenes Kobayashi et at. found that several transition metal salts displayed high catalytic activity in aza-Michael reactions of enones with carbamates, while conventional Lewis acids (BF3-OEt2, A1C13, TiCl4...) were much less active. 

Neutral scandium amido complexes have been developed as viable catalysts for intramolecular hydroamination of alkenes, such as MeC H(NH2)CH2CH2CH=CH2. 

An yttrium(III) complex derived from ligand (100) has been shown to be a superior catalyst for enantioselective intramolecular hydroaminations of alkenes that provide cyclic amines with enantioselectivities ranging from 69 to 89% ee,132... 

Organolanthanides catalyze the hydroamination of alkenes and alkynes, via the reaction sequence... 

Reactions of intramolecular hydroamination of alkenes, alkynes, and allenes with the formation of A-heterocycles in the presence of lanthanocene catalysts 02CRV2161. 

Stoichiometric reaction of the cationic catalyst 122 with 2,2-diphenyl-4-pentenylamine afforded the cationic amido complex 129 characterized by NMR (Scheme 44). The catalytic studies suggested that 129 was an active catalyst for the hydroamination of alkenes [82]. 

Scheme 11.1 Cold catalyzed asymmetric hydroamination of alkenes with cyclic ureas [12].

Group 4 bis(amidate)bis(amido) complexes have also been identified as precatalysts for the more challenging hydroamination of alkenes. The majority of investigations in this field focus on the intramolecular cychzation of aminoalkenes with zirconium-based catalysts. [64e] Neutral group 4 bis(amidate) zirconium amido or imido complexes are efficient precatalysts for the intramolecular cychzation of primary amines to form pyrrolidine and piperidine products (Scheme 12). The monomeric imido complex can be generated by reaction of the bis(amido) complex with 2,6-dimethylaniline and trapped with triphenylphosphine oxide. [64e] The bis(amido) and imido complexes... 

Aliphatic amines are amongst the most important bulk and fine chemicals in the chemical and pharmaceutical industry [13]. Hydroaminomethylation of alkenes to amines presents an atom-economic, efficient and elegant synthetic pathway towards this class of compounds. In hydroaminomethylation a reaction sequence of hydroformylation of an alkene to an aldehyde with subsequent reductive amina-tion proceeds in a domino reaction (see Eq. 4) [14]. Recently, the highly selective hydroamination of alkenes with ammonia to form linear primary and secondary aliphatic amines with a new Rh/Ir catalytic system (] Rh(cod)Cl 2], ] Ir(cod)Cl 2], aqueous TPPTS solution) has been described (see Scheme 2) [15]. The method is of particular importance for the production of industrially relevant, low molecular weight amines. 

Catalytic asymmetric hydroamination of alkenes can be achieved using early and late transition metal catalysts and lanthanide-based catalytic... 

Preparation of aliphatic amines by direct hydroamination of alkenes with amines is a highly desirable reaction. However, except for the well-established hydroamination of 1,3-dienes via 7r-allylpalladiums, no smooth hydroamination of simple alkenes is known. As a breakthrough, Kawatsura and Hartwig reported that the hydroamination of styrene derivatives with aniline is catalyzed by Pd(TFA)2 and DPPF in the presence of trifluoroacetic acid (TFA) or triflic acid as a cocatalyst to afford the branched amine 24 regioselectively in 99 % yield. Formation of the branched amine 24 offers an opportunity of asymmetric amination. They obtained the (5)-amine 25 in 80 % yield with 81 % ee using (/ )-BINAP as a chiral ligand [14]. The reaction is explained by insertion of styrene to the H-Pd bond and nucleophilic attack of amine on an fj -benzylpalladium complex [15]. Hii and coworkers obtained the amine 24 with 70 % ee in 75 % yield using the dicationic Pd complex, [Pd(MeCN)(H20)(/ -BINAP)](0Tf)2 [16]. 

Hydroamination is an atom-economical process for the synthesis of industrially and pharmaceutically valuable amines. The hydroamination reaction has been studied intensively, including asymmetric reactions, and a variety of catalytic systems based on early and late transition metals as well as main-group metals have been developed." However, Group 5 metal-catalysed hydroaminations of alkenes had not been reported until Hultzsch s work in 2011. Hultzsch discovered that 3,3 -silylated binaphtho-late niobium complex 69 was an efficient catalyst for the enantioselective hydroaminoalkylation of iV-methyl amine derivatives 70 with simple alkenes 71, giving enantioselectivities up to 80% (Scheme 9.30). Enantiomerically pure (l )-binaphtholate niobium amido complex 69 was readily prepared at room temperature in 5 min via rapid amine elimination reactions between Nb(NMe2)5 and l,l-binaphthyl-2-ol possessing bullqr 3,3 -silyl substituents. Since the complex prepared in situ showed reactivity and selectivity identical... 

Scheme 22 Intermolecular hydroamination of alkenes using mono- and bimetallic La complexes (61-63)...

As discussed in Chapter 9, the insertion of olefins and alk)nes into metal-amido complexes is limited to a few examples. Such insertion reactions are proposed to occur as part of the mechanism of the hydroamination of norbomene catalyzed by an iridium(I) complex and as part of the hydroamination of alkenes and alkynes catalyzed by lanthanide and actinide metal complexes. This reaction was clearly shown to occur with the iridium(I) amido complex formed by oxidative addition of aniline, and this insertion process is presented in Chapter 9. The mechanism of the most active Ir(I) catalyst system for this process involving added fluoride is imknown. 

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