Titanium tetrachloride, as Lewis acid

This reaction is a formal asymmetric aldol addition following a modified Evans protocol. The enolate 26 is formed at 0 °C in the presence of one equivalent of titanium tetrachloride as Lewis acid and two equivalents diisopropylethylamine (Hunig s base) as proton acceptor. Selectively the Z-enolate is formed. The carbon-carbon bond formation takes place under substrate control of the Tvan.v-auxiliary, whose benzyl group shields the, v/-face of the enolate. 

Lewis acids are defined as molecules that act as electron-pair acceptors. The proton is an important special case, but many other species can play an important role in the catalysis of organic reactions. The most important in organic reactions are metal cations and covalent compounds of metals. Metal cations that play prominent roles as catalysts include the alkali-metal monocations Li+, Na+, K+, Cs+, and Rb+, divalent ions such as Mg +, Ca +, and Zn, marry of the transition-metal cations, and certain lanthanides. The most commonly employed of the covalent compounds include boron trifluoride, aluminum chloride, titanium tetrachloride, and tin tetrachloride. Various other derivatives of boron, aluminum, and titanium also are employed as Lewis acid catalysts. 

As Lewis acid, titanium tetrachloride, boron trifluoride or ethylaluminum dichloride is often used. The stereochemical outcome of the reaction strongly depends on the Lewis acid used. The Sakurai reaction is a relatively new carbon-carbon forming reaction, that has been developed into a useful tool for organic synthesis. ... 

Ghosh has also shown that cis- l-(arylsulfonamido)-2-indanols could be used as excellent chiral auxiliaries in Diels-Alder reaction.85 Reaction of 80 with cyclopentadiene using a variety of Lewis acids led to 81 in good yield, with endo. exo ratios superior to 99 1 and diastereoselectivities ranging from 72% to 92%. The best selectivities were observed using titanium tetrachloride as the Lewis acid. The high degree of diastereoselection was presumed to result from effective metal chelation (Scheme 24.17). 

The demand for environmentally friendly chemistry and its widespread applicability have made water an increasingly popnlar solvent for organic transformations. Mixtures of water and other solvents snch as tetrahydrofnran are now commonly anployed for a number of organic transformations. For instance, the Lewis acid catalysed aldol reaction of silyl enol ethers, commonly known as the Mnkaiyama aldol reaction, which was firstly reported in the early seventies, can be carried ont in snch media. With titanium tetrachloride as the catalyst this reaction proceeds regioselectively in high yields, but the reaction has to be carried ont strictly nnder non-aqneons conditions in order to prevent decomposition of the catalyst and hydrolysis of the sUyl enol ethCTS. In the absence of the catalyst it was observed that water had a beneficial influence on this process (Table 4, entry D) . Nevertheless, the yields in the nncatalysed version WCTe still unsatisfactory. Improved results were obtained with water-tolerant Lewis acids. The first reported example for Lewis acid catalysis in aqueous media is the hydroxymethylation of silyl enol ethers with commercial formaldehyde solution using lanthanide trillates. In the meantime, the influence of several lanthanide triflates in cross-aldol reactions of various aldehydes was examined " " ". The reactions were most effectively carried out in 1 9 mixtures of water and tetrahydrofnran with 5-10% Yb(OTf)3, which can be reused after completion of the reaction (Table 19, entry A). Although the realization of this reaction is quite simple, the choice of the solvent is crucial (Table 20). 

Sung and coworkers have investigated titanium tetrachloride as a catalyst for nucleophilic substitution reactions of f-butyl alcohol and ben l alcohols containing 71-donating substituents with a variety of nucleophiles, obtaining excellent conversions and selectivities compared to other Lewis acids, even in the presence of primary or secondary alcohols (Scheme 5.12). ... 

The pivotal step in this sequence is an electrophilic substitution on indole. Although the use of l,3-dithian-2-yl carbanions is well documented, it has been shown only recently that 1,3-dithian-2-yl carbenium ions can be used in a Priedel-Crafts type reaction. This was accomplished initially using 2-methoxy-l,3-dithiane [1,3-Dithiane, 2-methoxy-] or 2-metlioxy-l,3-dithiolane [1,3-Dithiolane, 2-methoxy-] and titanium tetrachloride [Titanate(l —), tetrachloro-] as the Lewis acid catalyst.9 2-Substituted lysergic acid derivatives and 3-substituted indoles have been prepared under these conditions, but the method is limited in scope by the difficulties of preparing substituted 2-methoxy-1,3-dithianes. l,3-Dithian-2-yl carbenium ions have also been prepared by protonation of ketene dithioacetals with trifluoroacetic acid,10 but this reaction cannot be used to introduce 1,3-dithiane moieties into indole. 

The use of oxygen-containing dienophiles such as enol ethers, silyl enol ethers, or ketene acetals has received considerable attention. Yoshikoshi and coworkers have developed the simple addition of silyl enol ethers to nitroalkenes. Many Lewis acids are effective in promoting the reaction, and the products are converted into 1,4-dicarbonyl compounds after hydrolysis of the adducts (see Section 4.1.3 Michael addition).156 The trimethylsilyl enol ether of cyclohexanone reacts with nitrostyrenes in the presence of titanium dichloride diisopropoxide [Ti(Oi-Pr)2Cl2], as shown in Eq. 8.99.157 Endo approach (with respect to the carbocyclic ring) is favored in the presence of Ti(Oi-Pr)2Cl2. Titanium tetrachloride affords the nitronates nonselectively. 

Usually the stronger acids are also the more effective co-catalysts, but exceptions to this rule are known. Trichloroacetic acid, but not the equally strong picric acid, will co-catalyze the system isobutene-titanium tetrachloride in hexane.2 8 Some Lewis acid-olefin systems will not polymerize at all in the absence of a co-catalyst, an example being isobutene with boron trifluoride.2 4 This fact, together with the markedly slower reaction usual with carefully dried materials, has nourished the current suspicion that a co-catalyst may be necessary in every Lewis acid-olefin polymerization. It is very difficult to eliminate small traces of water which could act as a co-catalyst or generate mineral acid, and it may well be that the reactions which are slower when drier would not go at all if they could be made completely dry. 

Pentadienyltrimethylstannanes undergo regioselective conjugate additions to aldehydes, catalysed by Lewis acids. The dominant product obtained depends on the catalyst used, as shown in reaction 46. In the case of titanium tetrachloride catalysis the reaction is also stereoselective and only one diasteroisomer is obtained297. Reaction with chiral aldehydes leads to asymmetric induction with similar organotin compounds298. 

Brimble and coworkers172 reported the asymmetric Diels-Alder reactions between quinones 265 bearing a menthol chiral auxiliary and cyclopentadiene (equation 73). When zinc dichloride or zinc dibromide was employed as the Lewis acid catalyst, the reaction proceeded with complete endo selectivity, but with only moderate diastereofacial selectivity affording 3 1 and 2 1 mixtures of 266 and 267 (dominant diastereomer unknown), respectively. The use of stronger Lewis acids, such as titanium tetrachloride, led to the formation of fragmentation products. Due to the inseparability of the two diastereomeric adducts, it proved impossible to determine which one had been formed in excess. 

The regioselectivity of Michael additions of thiolates to 2,4-dienones can be altered drastically by variation of the reaction conditions and addition of Lewis acids to the reaction mixture. Lawton and coworkers examined the reaction of 2-mercaptoethanol with l-(3-nitrophenyl)-2,4-pentadien-l-one and observed a high regioselectivity in favor of the 1,6-addition product at 45 °C (equation 42)123,124. Lowering of the reaction temperature caused an increase in the amount of 1,4-adduct, and at —40°C, a product ratio of 40 60 was found. These events suggest that kinetic control favors the 1,4-addition product whereas the 1,6-adduct is thermodynamically more stable. If, however, the reaction was carried out with a complex of the dienone and titanium tetrachloride, only the 1,4-adduct was isolated after hydrolytic workup123. Obviously, this product is trapped as a metal chelate which prevents formation of the 1,6-adduct by retro-Michael/Michael addition. In the absence of the chelating Lewis acid, the 1,4-addition product can indeed be converted... 

A number of methods that utilize enolsilanes directly in the aldol process with either aldehydes or acetals have been developed recently. These reactions may be catalyzed with either Lewis acids such as titanium tetrachloride (73) or with fluoride ion (74). 

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