Titanium complexes synthesis

Amidinato-amido chloro complexes, with Ti(IV), 4, 335-336 Amidinato-imido titanium complexes, synthesis, 4, 431 -32 Amidinato ligands... 

Cossy J, BouzBouz S, Pradaux F, Willis C, Belosta V. Chiral titanium complexes. Synthesis of optically active unsaturated alcohols, diols, pol)fpropionates and their use in the synthesis of biologically active compounds. Synlett 2002 1595-1606. 

The advantages of titanium complexes over other metallic complexes is high selectivity, which can be readily adjusted by proper selection of ligands. Moreover, they are relative iaert to redox processes. The most common synthesis of chiral titanium complexes iavolves displacement of chloride or alkoxide groups on titanium with a chiral ligand, L ... 

Titanium, tetrakis(trimethysilyl)oxy-, 3, 334 Titanium, tetranitrato-stereochemistry, 1,94 Titanium, triaquabis(oxalato)-structure, I, 78 Titanium, tris(acetylacetone)-structurc, 1,65 Titanium alkoxides oligomeric structure, 2,346 synthesis ammonia, 2, 338 Titanium chloride photographic developer, 6,99 Titanium complexes acetylacetone dinuclear, 2, 372 alkyl... 

Scheme 17 Synthesis of a titanium pentasulfide from the dimethyl titanium complex...

The OEt-substituted Zr(IV)-boratabenzene complex has been employed in an interesting dual-catalyst approach to the synthesis of branched polyethylene.47 Capitalizing on the ability of this boratabenzene complex to generate 1-alkenes (Scheme 25) and the ability of the titanium complex illustrated in Scheme 27 to copolymerize ethylene and 1-alkenes, with a two-catalyst system one can produce branched polyethlene using ethylene as the only monomer (Scheme 27). The structure and properties of the branched polyethylene can be altered by adjusting the reaction conditions. 

Scheme 51 summarizes Mikami s synthesis of (R)-35, employing the car-bonyl-ene reaction of isoprene (A) with glyoxylate (B) to give C as catalyzed by a modified binaphthol-titanium complex [77]. 

Tomita K, Petrykin V, Kobayashi M, Shiro M, Yoshimura M, Kakihana MA (2006) Water-soluble titanium complex for the selective synthesis of nanocrystaUine brookite, rutile, and anatase by a hydrothermal method. Angew Chem Int Edit 118 2438-2441... 

The enantiopure acyclic and cyclic allyl sulfoximines 13 and 14, respectively, required for the synthesis of the corresponding titanium complexes 1 and 2, are available from sulfoximine 12 [13] and the corresponding aldehydes and cycloal-kanones by the addition-elimination-isomerization route, which can be carried... 

Scheme 1.3.5 Synthesis of cyclic and acyclic chiral sulfonimidoyl-substituted bis(allyl)titanium complexes.

Scheme 1.3.7 Synthesis of chiral sulfonimidoyl-substituted mono(allyl)titanium complexes.

A full account5 describes the enantioselective carbonyl-ene reaction of glyoxylate esters catalyzed by a binaphthol-derived chiral titanium complex that is potentially useful for the asymmetric synthesis of a-hydroxy esters of biological and synthetic importance.6 The present procedure is applicable to a variety of 1,1-disubstituted olefins to provide ene products in extremely high enantiomeric purity by the judicious choice of the dichloro or dibromo chiral catalyst (see Table). In certain glyoxylate-ene reactions involving removal of a methyl hydrogen, the dichloro catalyst... 

We began our synthesis by finding the optimum reaction conditions for the catalytic asymmetric cyanosilylation of ketone 28 (Table 1). Based on previous studies,30 the titanium complex of a D-glucose derived ligand (catalyst 32 or 33) generally gives (/ )-ketone cyanohydrins, which is required for a synthesis of natural fostriecin. 

Bis(arene)hafnium complexes, characteristics, 4, 697 Bis(arene)iron dications, characteristics, 6, 173 Bis(arene)niobium complexes, characteristics, 5, 95 Bis(arene)titanium(0) complexes, characteristics, 4, 243-244 Bis(arene)tricarbonylchromium complex, synthesis, 5, 258... 

Homoleptic tetrazincates, characteristics, 2, 346 Homoleptic titanium(III) complexes, with -ligands, 4, 282 Homoleptic trizincates, characteristics, 2, 345 Homoleptic vanadium(III) alkyl complexes synthesis and structure, 5, 12 VMes3 reactivity, 5, 12... 

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