Alkynes titanium

Since the hybridization and structure of the nitrile group resemble those of alkynes, titanium carbene complexes react with nitriles in a similar fashion. Titanocene-methylidene generated from titanacyclobutane or dimethyltitanocene reacts with two equivalents of a nitrile to form a 1,3-diazatitanacyclohexadiene 81. Hydrolysis of 81 affords p-ketoena-mines 82 or 4-amino-l-azadienes 83 (Scheme 14.35) [65,78]. The formation of the azati-tanacyclobutene by the reaction of methylidene/zinc halide complex with benzonitrile has also been studied [44]. 

An efficient isomerization of aliphatic and cyclic olefins is achieved using well-defined bis-Cp alkyne titanium complexes as catalysts. These complexes isomerize 1-alkenes to internal alkenes under mild conditions. The titanium complex can be recovered quantitatively. Cyclic olefins, for example, cyclohexadienes, also undergo... 

Carbon-nitrogen bond formation is an important subject in the organic synthesis [301], and hydroamination is an atom-efficient process for the generation of amines and imines from olefins, allenes, and alkynes. Titanium-mediated hydroamination was among the most useful protocols thus far developed for this reaction. By using unsymmetrical olefins and alkynes, the addition of HNR2 can in principle lead to two isomeric products, where the isomeric ratio is usually dependent on the type of titanium catalyst used. 

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. ... 

The guanidinate-supported titanium imido complex [Me2NC(NPr02l2Ti = NAr (Ar = 2,6-Me2C6H3) (cf. Section IILB.2) was reported to be an effective catalyst for the hydroamination of alkynes. The catalytic activity of bulky amidinato bis(alkyl) complexes of scandium and yttrium (cf. Section III.B.l) in the intramolecular hydroamination/cyclization of 2,2-dimethyl-4-pentenylamine has been investigated and compared to the activity of the corresponding cationic mono(alkyl) derivatives. 

Alkenes and alkynes can also add to each other to give cyclic products in other ways (see 15-61 and 15-63). The first exclusive exo-dig carbocyclization was reported using HfCU as a catalyst. Alkynes also add to alkenes for form rings in the presence of a palladium catalyst or a zirconium catalyst. " Carbocyclization of an alkene unit to another alkene unit was reported using an yttrium catalyst and alkenes add to alkynes to give cyclic compounds with titanium catalysts. ... 

As in the P(III) chemistry above, both late metal (Pd) and lanthanide catalysts have been used for P(V)-H additions to alkynes, alkenes, aldehydes, and imines. In addition, titanium, aluminum, and zinc catalysts have been employed. Typical P(V) substrates include dialkyl phosphites P(0R)2(0)H and phosphine oxides PR2(0)H. 

A variety of aldehyde/alkyne reductive couplings involving the stoichiometric use of early transition metals (Ti and Zr) have been developed (Scheme 27) [68-70]. The low cost and ease of handling of titanium alkox-ides render these stoichiometric processes very practical despite the lack of catalytic turnover. Recent variants of stoichiometric processes involving titanium alkoxides have demonstrated impressive scope in relatively complex applications [71-73]. 

Scheme 27 Titanium alkoxide-based strategy for aldehyde/alkyne reductive coupling...

Although the titanium-based methods are typically stoichiometric, catalytic turnover was achieved in one isolated example with trialkoxysilane reducing agents with titanocene catalysts (Scheme 28) [74], This example (as part of a broader study of enal cyclizations [74,75]) was indeed the first process to demonstrate catalysis in a silane-based aldehyde/alkyne reductive coupling and provided important guidance in the development of the nickel-catalyzed processes that are generally more tolerant of functionality and broader in scope. 

F. Sato developed titanium (Il)-based c/s-reduction of alkynes as shown in Scheme 5 [14], and the method was applied to the synthesis of pheromones by Kitching (Scheme 6) [15]. This titanium (Il)-based reaction gives pure (Z)-alkenes. Kitching summarized the contemporary methods for the synthesis of skipped polyynes and their reduction to skipped polyenes [15]. 

Kitching employed the titanium (Il)-based czs-reduction of alkynes in their synthesis of (3 ,8Z,llZ)-3,8,ll-tetradecatrienyl acetate (9), the pheromone of the moth Scrobipalpuloides absoluta as shown in Scheme 15 [15]. 

Finally, Odom and co-workers reported a titanium-catalyzed three-component coupling between primary amines, alkynes, and isonitriles for the preparation of a, 3-unsaturatcd /3-iminoamines in good yields (Scheme 35).121 Beside the three-component coupling product, an. V,.V-disubstituted formamidine and an imine were also identified as minor... 

Based on the established mechanism for titanium-catalyzed hydroamination, the authors propose a reversible reaction between a titanium imide complex and the alkyne to form metalloazacyclobutene 86, which in turn undergoes 1,1-insertion of the isonitrile into the Ti-C bond. The generated five-membered ring iminoacyl-amido complex 87 with the new C-C bond is protonated by the primary amine to afford the desired three-component coupling product, with regeneration of the catalytic imidotitanium species. Very recently, titanium-catalyzed carbon-carbon bond-forming reactions have been reviewed.122... 

Similar to Cp2TiCl2, T OPr1) as a less expensive precursor, can also be utilized for the synthesis of titanium-alkyne complexes.13 The reactivity of the (Pr10)2Ti-alkyne complexes toward a variety of substrates has been investigated.14 In the case of unsymmetrical alkynes as a starting material, the less hindered carbon of the resultant... 

The bisfunctionalization of alkynes by both C02 and another electrophile can also be achieved, as shown in Scheme 9.17,17a The titanium-carbon bond in the titanacycle complex 31, which was formed by reaction of C02 with the titanacyclopropene 30, can be substituted with various electrophiles. For example, its reaction with NBS or I2 afforded the synthetically useful vinyl bromide or iodide 32, respectively, while the reaction with D20 yielded the /3-deuterated a,/ -unsaturated carboxylic acid. When an aldehyde such as PhCHO was used as an electrophile, butenolide 33 was produced after acidic workup. 

Although terminal acetylenes themselves do not form stable titanium—acetylene complexes upon reaction with 1, the reaction with terminal alkynes having a keto group at the 5- or y-position induces an intramolecular cyclization, apparently via the above titanium-acetylene complex to afford the four- and five-membered cycloalkanols, as shown in Eq. 9.6 [28]. 

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