Allylic aryl allyl ether

Lithium diphenyphosphide (THF, 25°, 2 h HCl, H2O, 87% yield) selectively cleaves an aryl methyl ether in the presence of an ethyl ether.It also cleaves a phenyl benzyl ether and a phenyl allyl ether to phenol in 88% and 78% yield, respectively. ... 

NaAlH2(0CH2CH20CH3)2, PhCH3, reflux, 10 h, 62% yield/ An aryl allyl ether is selectively cleaved by this reagent (which also cleaves aryl benzyl ethers) in the presence of an A-allylamide. 

DMSO, H2O, 90°, 79-87% yield. These conditions are only effective for primary allylic and homoallylic, primary benzylic, and aryl TBDMS ethers. ... 

The rearrangement of an ether 1 when treated with a strong base, e.g. an organo-lithium compound RLi, to give an alcohol 3 via the intermediate a-metallated ether 2, is called the Wittig rearrangement. The product obtained is a secondary or tertiary alcohol. R R can be alkyl, aryl and vinyl. Especially suitable substrates are ethers where the intermediate carbanion can be stabilized by one of the substituents R R e.g. benzyl or allyl ethers. 

Michael addition to give the azaheterocycles 7-39 through a favorable 6-exo-trig ring closure (Scheme 7.13). Even highly sensible substrates such as aryl-allyl ethers and amines could be transformed to the desired products in excellent yields. 

Nickel-bpy and nickel-pyridine catalytic systems have been applied to numerous electroreductive reactions,202 such as synthesis of ketones by heterocoupling of acyl and benzyl halides,210,213 addition of aryl bromides to activated alkenes,212,214 synthesis of conjugated dienes, unsaturated esters, ketones, and nitriles by homo- and cross-coupling involving alkenyl halides,215 reductive polymerization of aromatic and heteroaromatic dibromides,216-221 or cleavage of the C-0 bond in allyl ethers.222... 

Gold(I)-catalyzed synthesis of dihydrobenzo[ >]furans from aryl allyl ethers was reported as depicted below <06SL1278>. Highly efficient AuCl3/AgOTf-catalyzed atom-economical annulation of phenols with dienes was developed. This annulation generated various dihydrobenzo[ >]furans under mild conditions <06OL2397>. 

Diastereoselective syntheses of dihydrobenzo[f>]furans have been accomplished by a rhodium-catalyzed regioselective and enantiospecific intermolecular allylic etherification of o-iodophenols as a key step, providing the corresponding aryl ally ether 122, which leads to a dihydrobenzo[b]furan by treatment of the intermediate aryl iodide with tris(trimethylsilyl)silane and triethylborane at room temperature in the presence of air <00JA5012>. 

The ruthenium-catalyzed isomerization of aryl allyl ethers or amines followed by ring-closing metathesis with ruthenium catalyst 1 furnishes fused benzo-heterocycles in good yield (Scheme 40).66 67... 

A polymer-supported iridium catalyst 4 has been prepared and used in the isomerization of the double bonds in aryl allyl ethers and aryl allylic compounds with excellent trans-scIcctivity and without conventional workup procedures (Scheme 45).73... 

Using AD mix-a or AD mix-/ as the dihydroxylation agent, various olefins can be dihydroxylated with high ee.57,67b 72 As an example, in Scheme 4-33, aryl-allyl ethers undergo dihydroxylation yielding products with good ee. The procedure can be used as an alternative for the synthesis of (2S )-propranolol.73... 

When, furthermore, phenols (368) are coupled with 1 in the presence of a Pd° catalyst, the phenoxy-methyl-1,3-dienes 369 are produced [158]. As aryl allyl ethers, these can be made to undergo a Claisen rearrangement (205 °C, DMF) and the ensuing 2-(l,3-dienylmethyl)phenols 370 finally cydize in the presence of a trace of acid to a mixture of exo-methylene chromans 371 (major product) and dihydrobenzofur-ans 372 - a remarkable generation of functional and structural complexity from simple starting materials with 100% atom economy and underlining impressively the synthetic versatility of modern allene chemistry ... 

Scheme 85 Cleavage of an aryl allyl ether for deprotection of a phenol.

Finally, addition of the carbanions derived from 83 to non-enolizable aldehydes is a facile process. Aryl and tertiary alkyl aldehydes gave trimethylsilyl allyl ethers 85 by a [1,4]-Brook isomerization (equation 30). The stereochemistry of the intermediate alkoxides 84 dramatically influences the reaction conditions required . 

Tab. 10.7 summarizes the results of the application of rhodium-catalyzed allylic etherification to a series of ortho-substituted phenols. The etherification tolerates alkyls, including branched alkanes (entries 1 and 2), aryl substituents (entry 3), heteroatoms (entries 4 and 5), and halogens (entry 6). These results prompted the examination of ortho-disubstituted phenols, which were expected to be more challenging substrates for this type of reaction. Remarkably, the ortho-disubstituted phenols furnished the secondary aryl allyl ethers with similar selectivity (entries 7-12). The ability to employ halogen-bearing ortho-disubstituted phenols should facilitate substitutions that would have proven extremely challenging with conventional cross-coupling protocols. 

This methodology was applied to a two-step sequence for the preparation of enantio-merically enriched dihydrobenzo[h]furans (Scheme 10.11) [46]. Rhodium-catalyzed allylic etherification of (S)-47 (>99% ee), with the sodium anion of 2-iodo-6-methyl-phenol, furnished the corresponding aryl allyl ethers (S)-48/49 as a 28 1 mixture of regioisomers favoring (S)-48 (92% cee). Treatment of the aryl iodide (S)-48 with tris(trimethylsilyl)silane and triethylborane furnished the dihydrobenzo[h]furan derivatives 50a/50b as a 29 1 mixture of diastereomers [43]. 

Tab. 10.8 summarizes the application of rhodium-catalyzed allylic etherification to a variety of racemic secondary allylic carbonates, using the copper(I) alkoxide derived from 2,4-dimethyl-3-pentanol vide intro). Although the allyhc etherification is tolerant of linear alkyl substituents (entries 1-4), branched derivatives proved more challenging in terms of selectivity and turnover, the y-position being the first point at which branching does not appear to interfere with the substitution (entry 5). The allylic etherification also proved feasible for hydroxymethyl, alkene, and aryl substituents, albeit with lower selectivity (entries 6-9). This transformation is remarkably tolerant, given that the classical alkylation of a hindered metal alkoxide with a secondary alkyl halide would undoubtedly lead to elimination. Hence, regioselective rhodium-catalyzed allylic etherification with a secondary copper(l) alkoxide provides an important method for the synthesis of allylic ethers. 

Larock, R. C. Stinn, D. E. Synthesis of Benzofurans via Palladium-Promoted Cyclization of Ortho-Substituted Aryl Allyl Ethers, Tetrahedron Lett. 1988,29,4687-4690. 

The Wittig rearrangement is the base-catalyzed 1.2-shift of an alkyl, allyl. benzyl, or phenyl group of an ether from oxygen to carbon. A patent claim describes the conversion of aryl arylmethyl ethers such as 21 into diarylmethanols such as 22.14... 

Such rearrangements are quite general for aryl allyl ethers and are called Claisen rearrangements. They are examples of the pericyclic reactions discussed in Section 21-10D. (See Exercise 26-45.)... 

Deprotection of allyl aryl ethers is accomplished by protonolysis with palladium on activated charcoal in methanol solution in the presence of toluene-p-sulphonic acid,42 or by reduction with sodium bis(2-methoxy-ethoxy)aluminium hydride in toluene solution43 (Aldrich). This latter reagent also cleaves aryl benzyl ethers. 

Recall that the Claisen rearrangement converts an aryl allyl ether to an ortho-substituted allyl phenol. The presence of an allyl substituent in the product ortho to an aryl ether thus suggests the following retrosynthesis ... 

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