Titanium IV chloride

When titanium dissolves in dilute hydrochloric acid, a violet solution containing titanium(III) ions is formed. This solution rapidly decolorises acidified aqueous potassium permanganate at room temperature. Titanium(IV) chloride is a colourless covalent liquid completely hydrolysed by water. Titanium(III) chloride forms hydrated titanium(III) ions in water and disproportionates when heated in a vacuum. 

The Stock Oxidation-Number System. Stock sought to correct many nomenclature difficulties by introducing Roman numerals in parentheses to indicate the state(s) of oxidation, eg, titanium(II) chloride for TiCl2, iron(II) oxide for FeO, titanium(III) chloride for TiCl, iron(III) oxide for Fe203, titanium(IV) chloride for TiCl, and iron(II,III) oxide for Fe O. In this system, only the termination -ate is used for anions, followed by Roman numerals in parentheses. Examples are potassium manganate(IV) for K2Mn02, potassium tetrachloroplatinate(II) for K PtCl, and sodium hexacyanoferrate(III) for Na3Fe(CN)3. Thus a set of prefixes and terminations becomes uimecessary. 

Bis(ethyl)titanium(IV) chloride [2247-00-9] M 177.0. Crystd from boiling toluene. 

To create a setting favorable for the formation of the E-ring of ginkgolide B, it is first necessary to modify the reactivity potential of ring F in 23. Exposure of a solution of 23 in methylene chloride to 1,3-propanedithiol and titanium(iv) chloride at 0°C results in the formation of dithiane 24 in quantitative yield. Oxidation of the primary alcohol with PDC in the presence of acetic acid gives aldehyde 25 in a yield of 75 %. 

The pharmaceutical interest in the tricyclic structure of dibenz[6,/]oxepins with various side chains in position 10(11) stimulated a search for a convenient method for the introduction of functional groups into this position. It has been shown that nucleophilic attack at the carbonyl group in the 10-position of the dibenzoxepin structure renders the system susceptible to water elimination. Formally, the hydroxy group in the enol form is replaced by nucleophiles such as amines or thiols. The Lewis acids boron trifluoride-diethyl ether complex and titanium(IV) chloride have been used as catalysts. 

The formation of the isocorrolecarbaldehyde 5 may be best explained if one invokes 1,2-diol 4 as an intermediate of the McMurry coupling which would then react in a titanium(IV) chloride induced Wagner-Meerwein rearrangement to yield the isocorrole 5 as a minor product during... 

The transfer of an ethyl group, in particular, can be performed with high diastereoselectivity by the use of tetraalkyllead, activated with titanium(IV) chloride14"15 (Table 4). The order of addition of the reagents exhibits a strong influence on the chemical yield and diastercoselectiv-ity of the addition reaction. Typically, titanium(IV) chloride is added at -78CC to the aldehyde, followed by addition of tetraethyllead. Poor yields and diastereoselectivity are observed if titanium(IV) chloride is first added to tetraethyllead followed by addition of the aldehyde ... 

On the contrary, in the latter case, a total loss of stereoselectivity occurs68. TV-Bis-benzyl-a-amino aldehydes 1 (R = R3 = Bn) under the assistance of boron trifluoride, zinc bromide or tin(lV) chloride lead to the nonchclation-controlled adducts preferentially, whereas titanium(IV) chloride or magnesium bromide result in chelation control70. In some cases, the O-trimcthylsilyl cyanohydrins arc the primary products, but the workup procedure usually provides the desily-lated products. 

A similar dependence of the stereoselectivity on the solvent and reaction temperature was found with the x-oxo amides 9 derived from phenylglyoxylic acid (R = C6H5) and 2-oxopropanoic acid (R = CH3) with amine F (Table 23)15. Thus, the highest selectivity was observed under chelation-controlled conditions in the presence of the Lewis acid titanium(IV) chloride. 

The syn selectivity in the titanium(IV) chloride mediated reactions can be explained by an intermolecular chelation, with transition state 21A being sterically favored over 21B. On the other hand, nonchelation control governs the stereochemistry of the boron trifluoride mediated reactions. Thus, the sterically favored transition state 21 C leads to the observed anf/ -diastereo-mer12. 

Since the double-bond configuration is established in the final elimination step from a /t-silicon-(or tin-) substituted carbenium ion in a conformation of lowest energy, often high E selectivity is observed. In reactions of allylstannanes, catalyzed by tin(TV) chloride or titanium(IV) chloride, occasionally a metal exchange occurs, followed by the pericyclic addition pathway leading to the iwti-diastereomers17 19. A more detailed discussion is given in Section D.1.3.3.3.5. 

Allylsilanes or allylstannanes in the presence of a bidentate Lewis acid such as tin(IV) chloride, titanium(IV) chloride, zinc chloride, and magnesium bromide as well as diallylzinc, are promising choices (Table 1). 

The reactions of a-methyl-branched acylsilanes with 2-propenylmagnesium bromide exhibit surprisingly high diastereoselectivilies, although further improvement is accomplished by application of allyltrimethylsilane/ titanium(IV) chloride (> 100 I)27. The fluoride-induced desilylation proceeds with retention of configuration. 

The direct allylation of 2-phenylpropanal proceeds with much lower selectivity [2-propenylmagnesium bromide 73 27 allyltrimethylsilane/titanium(IV) chloride 67 33]27. 

Butenyl(trimethyl)silane reacts with aldehydes in the presence of titanium(IV) chloride to give sj/77-products with excellent stereoselectivity. Reactions of the (Z)-2-butenylsilane are less stereoselective although jyn-products are still preferred23. 

On treatment with trimethyl(2-propenyl)silane and titanium(IV) chloride, chiral methyl fi-formylcarboxylates give di- and tetra-substituted y-lactones with moderate to good stereoselectivity. Participation of seven-membered ring chelates was suggested65. 

Chelation control of the intramolecular reaction between an allylsilane and an aldehyde or ketone has been carefully investigated. Excellent stereoselectivity was found for cyclization of B-oxo esters using titanium(IV) chloride as the Lewis acid, less good selectivity for cyclization of /l-diketones70. 

A solution of 1.0 mmol of 2-acetyl alkenoate in 2.5 mL of CH2C1, is added slowly to a solution of 4.0 mmol of titanium(IV) chloride in 7.5 mL of CH-CL under an atmosphere of nitrogen at — 78 °C. The mixture instantaneously turns deep red. and is stirred at — 78 °C before being quenched by the addition of 5 mL of sat. aq potassium carbonate. The mixture is then partitioned between 10 mL of bt20 and 10 mL of water. The aqueous phase is extracted with three 10-mL portions of Et2(), and the extracts are combined, washed with 10 mL of brine, and dried over anhyd potassium carbonate. Concentration under reduced pressure gives the crude product. Product analysis is by capillary GC. 

An interesting and stereoselective synthesis of 1,3-diols has been developed which is based on Lewis acid promoted reactions of /f-(2-propenylsilyloxy (aldehydes. Using titanium(IV) chloride intramolecular allyl transfer takes place to give predominantly Ag/r-l,3-diols, whereas anti-1,3-diols, formed via an / / /-molecular process, are obtained using tin(IV) chloride or boron trifluoride diethyl ether complex71. 

Optically active (Z)-l-substituted-2-alkenylsilanes are also available by asymmetric cross coupling, and similarly react with aldehydes in the presence of titanium(IV) chloride by an SE process in which the electrophile attacks the allylsilane double bond unit with respect to the leaving silyl group to form ( )-s)vr-products. However the enantiomeric excesses of these (Z)-allylsilanes tend to be lower than those of their ( )-isomers, and their reactions with aldehydes tend to be less stereoselective with more of the (E)-anti products being obtained74. 

Trimethyl(l-phenyl-2-propenyl)silane of high enantiomeric excess has also been prepared by asymmetric cross coupling, and reacts with aldehydes to give optically active products in the presence of titanium(IV) chloride. The stereoselectivity of these reactions is consistent with the antiperiplanar process previously outlined75. 

Effective 1,4-asymmetric induction has been observed in reactions between 2-(alkoxyethyl)-2-propenylsilanes and aldehydes. The relative configuration of the product depends on the Lewis acid used. Titanium(IV) chloride, in the presence of diethyl ether, gave 1,4-ijn-products with excellent stereoselectivity with boron trifluoride-diethyl ether complex, the amt-isomer was the major product, but the stereoselectivity was less83. 

Excellent chelation control was observed using tributyl(2-propenyl)stannane and a-benzyloxy-cyclohexaneacetaldehyde with magnesium bromide or titanium(IV) chloride, whereas useful Cram selectivity was observed for boron trifluoride-diethyl ether complex induced reactions of the corresponding ferr-butyldimethylsilyl ether89. 

For a-benzyloxycyclohexaneacelaldehyde and 2-butenylstannanes, good chelation control was observed using zinc iodide and titanium(IV) chloride, but only weak synjanti selectivity. Better syn/anti selectivity was found using boron trifluoride-diethyl ether complex, but weak chelation control. Magnesium bromide gave excellent chelation control and acceptable syn/anli selectivity90. 

The best results were obtained with amides of (S)- or (/ )-3-methoxy-l-phenyl-2-propylamine, which gave, with linear aliphatic aldehydes, products with enantiomeric excesses greater than 75% using titanium(IV) chloride as the Lewis acid. A transition state involving coordination of the titanium by the carbonyl oxygens of both the amide and the aldehyde was proposed95. 

Titanium(IV) chloride induced re.ictionsof(1 -methyl-3-trimethylstannyI-l-butenyl)diisopropyl-carbamate and aldehydes proceed with a double 1,3-shift to give ami-products, also with effective asymmetric induction118. 1-Alkoxyallyltitanium trichlorides are involved. 

The titanium(IV) chloride induced reaction of an a-methyl-y-carbamoyloxyallylstannane, which is believed to involve the in situ generation of a chiral a-carbamoyloxytitanium species, gave products 3 and 4 in yields of ca. 85 %, whose configuration was determined by the reagent, not by the aldehyde118. 

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