Ethers, preparation from

The lithiation of allene can also be carried out with ethyllithium or butyl-lithium in diethyl ether (prepared from the alkyl bromides), using THF as a cosolvent. The salt suspension which is initially present when the solution of alkyllithium is cooled to -50°C or lower has disappeared almost completely when the reaction between allene and alkyllithium is finished. 

In some experiments the presence of hexane is undesirable in view of the volatility of the products. In these cases one can use butyllithium in pentane (prepared from butyllithium in hexane, by replacing the hexane with pentane see Exp. 10) or ethyllithium in diethyl ether, prepared from ethyl bromide and 11thiurn (see Exp. 1). 

The alkylations proceeded much more slowly, when ethyl- or butyllithium in diethyl ether, prepared from the alkyl bromides, had been used for the metallation of allene, in spite of the presence of THF and HMPT as co-solvents. 

Note 1. Butyl- or ethyllithium in diethyl ether, prepared from the alkyl bromide, contains LiBr, which may react with chlorine to form bromine, so that RCeC-Br will also be formed. 

To a refluxing solution 0. phenylmagnesium bromide in 650 ml of diethyl ether, prepared from 1.15 mol of broraobenzene (see Chapter 11, Exp. 5) was added 1.00 mol of ally] bromide at a rate such that refluxing was maintained (about 30 min). 

A solution of methylmagnesium bromide in 150 ml of diethyl ether, prepared from 0.5 mol of methyl bromide (see Chapter II, Exp. 5) was subsequently added in 20 min with cooling at about 20°C. After the addition the mixture was warmed for 2 h under reflux (the thermometer and gas outlet were replaced with a reflux condenser), a black slurry being formed on the bottom of the flask. The mixture was cooled in a bath of dry-ice and acetone and a solution of 30 g of ammonium chlori.de in 200 ml of water was added with vigorous stirring. The organic layer and four ethereal extracts were combined, dried over potassium carbonate and subsequently concentrated in a water-pump vacuum. Careful distillation of the residue through a 40-cm... 

To a mixture of 0.10 mol of 1-ethoxy-l,2-heptadiene (see this chapter, Exp. 13) and 120 ml of diethyl ether was added 1 g of copper(I) bromide. A solution of butyl magnesium bromide in about 200 ml of diethyl ether, prepared from 0.25 mol of butyl bromide (see Chapter II, Exp. 5) was added in 15 min. The reaction was weakly exothermic and the temperature rose slowly to about 32°C. The mixture was held for an additional 40 min at that temperature, then the black reaction mixture was... 

The p-cyanobenzyl ether, prepared from an alcohol and the benzyl bromide in the presence of sodium, hydride (74% yield), can be cleaved by electrolytic reduction (—2.1 V, 71% yield). It is stable to electrolytic removal ( — 1.4 V) of a tritylone ether [i.e., 9-(9-phenyl-10-oxo)anthiyl ether]. ... 

The tetrahydropyranyl ether, prepared from a phenol and dihydropyran (HCl/ EtOAc, 25°, 24 h), is cleaved by aqueous oxalic acid (MeOH, 50-90°, 1-2 h). ... 

Zn, HOAc, 25°, 1 h, 88-96% yield. Phenacyi andp-bromophenacyl ethers of phenols are stable to 1 % ethanolic alkali (reflux, 2 h), and to 5 N sulfuric acid in ethanol-water. The phenacyi ether, prepared from /3-naphthol, is cleaved in 82% yield by 5% ethanolic alkali (reflux, 2 h). 

A solution of diazomethane in 2.4 liters ether, prepared from 177 g (1.71 moles) of A-nitrosomethylurea and 530 ml of 40% aqueous potassium hydroxide, is added to 26.4 g (0.81 moles) 17 -acetoxyandrosta-1,4,6-triene-3-one in 250 ml ether. After 6 days at room temperature the ether is removed by distillation at reduced pressure and the residue is chromatographed on 1.5 kg of silica gel (deactivated with water 10% v/w). The product is eluted with methylene dichloride and recrystallized from diisopropyl ether-methylene dichloride to give 11 g (37 %) 17 -acetoxyandrosta-4,6-dien-3-one-[2a,la-c]-A -pyrazoline mp 161° (dec.) —91° (CHCI3) ... 

The tetrahydropyranyl ether, prepared from a phenol and dihydropyran (HCl/EtOAc, 25°, 24 h) is cleaved by aqueous oxalic acid (MeOH, 50-90°, 1-2 h). Tonsil, Mexican Bentonite earth, HSZ Zeolite, and H3[PW,204o] have also been used for the tetrahydropyranylation of phenols. The use of [Ru(ACN)3(triphos)](OTf)2 in acetone selectively removes the THP group from a phenol in the presence of an alkyl THP group. Ketals of acetophenones are also cleaved. ... 

Tetraphenyltellurophene To a suspension of 1,4-dilithiotetraphenyl-l,3-butadiene in 100 mL of ether, prepared from 10 g (56 mmol) of diphenyl acetylene and excess of lithium, is added over 15 min a solution of TeCl4 (5.3 g, 19.7 mmol). The green mixture is poured into a mixture of CH2CI2 and water, the organic phase is separated, filtered through anhydrous MgS04, filtered and evaporated. The residue is recrystallized from dichloromethane/ethanol, giving tetraphenyltellurophene 5.35 g (56%), m.p. 239°C. 

The infrared spectra of l,4-anhydro-3,5-0-methylene- and -2-0-methyl-DL-xylitol have been studied.60 The 2-methyl ether was obtained by converting l,4-anhydro-3,5-0-methylene-DL-xylitol into its monomethyl ether, and then hydrolyzing off the methylene group. A methyl ether prepared from the known l,4-anhydro-3,5-0-isopro-pylidene-2-O-methyl-DL-xylitol proved to be identical with this compound, thus establishing at the same time that the methylene group in the known acetal is attached to 0-3 and 0-5 of 1,4-anhydro-DL-xylitol. The methylene group, having a 1,3-dioxolane structure, was characterized by an absorption band at about 2800 cm 1. 

The disadvantage in using such symmetrical bislactim ethers is that half the chiral auxiliary ends up as part of the product molecule thus only half of the auxiliary can be recovered and reused. This drawback is avoided in the mixed bislactim ether prepared from a chiral auxiliary (L-valine) and a racemic amino acid (e.g., DL-alanine). Regiospecific deprotonation followed by diastereoselective alkylation leads to the required a-methyl amino acid ester (193) (83T2085) the de is >95%. In this method, the chiral auxiliary (L-valine) is recovered intact. (Scheme 59). 

Problem 14.14 (R)-2-Octanol and its ethyl ether are levorotatory. Predict the configuration and sign of rotation of the ethyl ether prepared from this alcohol by (a) reacting with Na and then CjHjBr (b) reacting in a solvent of low dielectric constant with concentrated HBr and then with CjHjO Na. ... 

To a stirred solution of 0.02 mole of an orange-red solution of potassium diphenylmethide in 150 ml of liquid ammonia and 50 ml of dry ethyl ether, prepared from 0.02 mole of KNH2 and 3.36 gm (0.02 mole) of diphenyl-methane, is added 2.5 gm (0.01 mole) of l,l-dichloro-2,2-diphenylethene. The reaction mixture darkens and then a precipitate forms. The reaction mixture is stirred until all the ammonia evaporates to leave a solid. The solid is recrystallized from chloroform-methanol to afford 3.1 gm (90%) of tetraphenylallene, m.p. 164°C. 

Cleavage conditions for alkyl benzyl ethers prepared from acid-labile benzyl alcohols are similar to those for the corresponding benzyl esters (Table 3.30). Aryl benzyl ethers, however, are generally cleaved more easily by acidolysis than esters or alkyl ethers. Phenols etherified with hydroxymethyl polystyrene, for instance, can even be released by treatment with TFA (Entry 1, Table 3.31). It has also been shown that Wang resin derived phenyl ethers are less stable than Wang resin derived esters towards refluxing acetic acid [29]. Alternatively, boron tribromide may be used to cleave aryl ethers from hydroxymethyl polystyrene [573],... 

The lithiated benzylic ether prepared from 79 is a carbon nucleophile. Under boron trifluoride catalysis10 it attacks diepoxide 6. In the process, the alkyl lithium reagent adds in a stepwise fashion to diepoxide 6, whereby the first addition is significantly more rapid than the second.7 One thus obtains only the monoadduct 24... 

Further examination of the fluoride ion-catalyzed asymmetric aldol reaction of the enol silyl ethers prepared from acetophenones and pinacolone with benzaldehyde using 4b and its pseudoenantiomer 4c revealed the dependence of the stereochemistry of the reactions on the hydroxymethyl-quinudidine fragment of the catalyst (Table 9.3) [10,15]. 

A solution of diazomethane in diethyl ether, prepared from 5 g (49 mmol) of N-nitrosomethylurea, was added to a cold solution of 4 mmol of the corresponding 2-arylmethylene-l,2,3,4-tetrahydronaphthalen-l-one 1 in 10 ml of benzene, and the mixture was left overnight (Scheme A. 10). The solvent was evaporated and the residue was recrystallized from ethanol. 

Radical cyclization of divinyl ethers prepared from the reaction of 1,3-dicarbonyl compounds and ethyl propynoate gave rise to trisubstituted furans as shown in Ae following example <03TL2125>. 

Since sUyl ynol ethers have an electron-rich triple bond, they are useful for Lewis acid catalyzed synthetic reactions. Lithium ynolates 175 are silylated by TIPSCl or TIPSOTf and TBSCl to afford the corresponding silyl ynol ethers 176 and 177, which are thermally stable and isolable, but sensitive toward acids (equation 71) . See also equations 9 and 10 in Section ll.C. An experimentally improved procedure for the purification of 176 derived from Kowalski s method is described. Lithium ynolate derived from Julia s method is also used for the preparation of 176. TMSCl and TESCl provide silyl ketenes 179, however, by C-silylation. These small silyl chlorides primarily gave the silyl ynol ethers 178, but, upon warming the reaction mixture, isomerization to the more stable silyl ketenes takes place. The soft electrophilic silyl chlorides like PhsSiCl afford silyl ketenes. Disi-lyl ynol ethers, prepared from ynolate dianions, are rearranged to disilylketenes mediated by salts . 

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