Titanium tetrachloride carbonyl compounds

Another titanium-based reagent for the methylenation of carbonyl compounds is that prepared from dibromomethane/zinc/titanium tetrachloride and related systems (Scheme 14.25) [48]. These systems transform a wide variety of carboxylic acid derivatives to terminal olefins in the same way as titanocene-methylidene does. 

Balme G, Gore J (1983) Conversion of acetals and ketals to carbonyl compounds promoted by titanium tetrachloride. J Org Chem 48 3336-3338... 

White and Weingarten [44] recently reported a novel method for converting carbonyl compounds to enamines using titanium tetrachloride and the free amine (Eq. 9). In this reaction the titanium tetrachloride acts as an effective... 

Silyl enol ethers undergo reaction with carbonyl compounds promoted by Lewis acids, but especially titanium tetrachloride. The reaction is thought to proceed via a titanium chelate which inhibits the reverse aldol process and the regiochemical integrity of the starting silyl enol ether is retained (Scheme 102).373... 

This procedure illustrates a general method for the preparation of crossed aldols. The aldol reaction between various silyl enol ethers and carbonyl compounds proceeds smoothly according to the same procedure (see Table I). Sllyl enol ethers react with aldehydes at -78°C, and with ketones near 0°C. Note that the aldol reaction of sllyl enol ethers with ketones affords good yields of crossed aldols which are generally difficult to prepare using lithium or boron enolates. Lewis acids such as tin tetrachloride and boron trifluoride etherate also promote the reaction however, titanium tetrachloride is generally the most effective catalyst. 

Synthetically even more versatile trifunctional intermediates result from the addition of carbonyl compounds onto methyl 2-siloxycyclopropanecarboxylates 92). Benzo-phenone, titanium tetrachloride, and 162, for instance, provide an excellent yield of the a-hydroxyalkylated y-oxoester 174, which predominates in the equilibrium with its cyclic hemiacetal 176 (y-lactol). It can undergo elimination to the unsaturated ester 175, but as Scheme 7 illustrates, 174/176 can also serve as the starting material to several highly substituted furan(one) derivatives. 

Titanium(lV) is a powerful but selective Lewis acid which can promote the coupling of allylsilanes with carbonyl compounds and derivatives. In the presence of titanium tetrachloride, benzalacetone reacts with allyltrimethylsilane by 1,4-addition to give 4-PHENYL-6-HEPTEN-2-ONE. Similarly, the enol silyl ether of cyclopentanone is coupled with f-pentyl chloride using titanium tetrachloride to give 2-(tert-PENTYL)CYCLOPENTANONE, an example of a-tert-alkylation of ketones. 

A study on the scope of the reaction applied to different types of carbonyl compounds (aldehydes, cyclic ketones and some substituted alkyl aryl ketones75) has been published. Two different secondary amines (pyrrolidine, morpholine) were used. Titanium tetrachloride on various supports (e.g. A1203) acted as effective dehydrating agents for the preparation of enamines from hindered ketones and secondary amines76. 

A standard method for enamine synthesis from aldehydes or ketones is to heat the carbonyl compound and the secondary amine in benzene or toluene and remove the water formed by azeotropic distillation. This method cannot, however, be used the preparation of enamines from methyl ketones which undergo self-condensation under these conditions. A procedure which overcomes these difficulties has been given by White and Weingarten [31]. The method employs anhydrous titanium tetrachloride as water scavenger. In the original procedure by White and Weingarten, titanium tetrachloride is added dropwise to a cooled... 

As previously mentioned, 1-alkynyltrialkylborates (18) have become increasingly important in the formation of carbon-carbon bonds via attack of electrophiles. However, such complexes cannot react with simple Qc,P-unsaturated carbonyl compounds such as methyl vinyl ketone, because of their weak electrophilicity. Recently it was ascertained that ,P-unsaturated carbonyl compounds react with 18 via a Michael-type reaction in the presence of titanium tetrachloride, and the usual alkaline hydrogen peroxide oxidation leads to the synthesis of 5-dicarbonyl compounds... 

The isolation of the initial aldol products from the condensation of the enolates of carbene complexes and carbonyl compounds is possible if the carbonyl compound is pretreated with a Lewis acid. As indicated in equation (9), the scope of the aldol reaction can also be extended to ketones and enolizable aldehydes by this procedure. The condensations with ketones were most successful when boron trifluoride etherate was employed, and for aldehydes, the Lewis acid of choice is titanium tetrachloride. The carbonyl compound is pretreated with a stoichiometric amount of the Lewis acid and to this is added a solution of the anion generated from the caibene complex. An excess of the carbonyl-Lewis acid complex (2-10 equiv.) is employed however, above 2 equiv. only small improvements in the overall yield are realized. 

Titanium tetrachloride promoted a three-component cyclization involving a carbonyl compound, an allylsilane, and an acetal, as shown in Eq. (69) [188]. The reaction was initiated by allyl addition to the aldehyde this was followed by acetal exchange and intramolecular Friedel-Crafts-type alkylation of the olefinic moiety. 

J32.1 Titanium tetrachloride promoted additions of aUenyisUanes to carbonyl compounds... 

The direct selenoacetalization of carbonyl compounds by selenols is by far the shortest and most convenient route to selenoacetals. The reaction is usually carried out at 20 C with zinc chloride (0.5 equiv. versus the carbonyl con x>und) and delivers rapidly (<3 h) and in reasonably good yields methyl and phenyl selenoacetals derived from aliphatic aldehydes and ketones and cyclic ketones (Scheme 69). Selenoacetalization is more difficult to achieve with hindered ketones, such as adamantanone and diisopropyl ketone, and with hindered aromatic carbtmyl compounds. In these cases the reaction is best achieved with titanium tetrachloride instead of zinc chloride and is often limited to the methylseleno derivatives (Scheme 78). Tris(methylseleno)borane offers the advantage of not requiring an acid catalyst and is particularly useful for the selenoacetalization of acid labQe aldehydes such as citronellal (Scheme 70, e). 

Titanium tetrachloride promoted additions of allenylsilanes to carbonyl compounds 2.53.22 [3 + 21 anneUttion strategies involving allenylsilanes... 

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