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Acetates, allylic

In contrast to oxidation in water, it has been found that 1-alkenes are directly oxidized with molecular oxygen in anhydrous, aprotic solvents, when a catalyst system of PdCl2(MeCN)2 and CuCl is used together with HMPA. In the absence of HMPA, no reaction takes place(100]. In the oxidation of 1-decene, the Oj uptake correlates with the amount of 2-decanone formed, and up to 0.5 mol of O2 is consumed for the production of 1 mol of the ketone. This result shows that both O atoms of molecular oxygen are incorporated into the product, and a bimetallic Pd(II) hydroperoxide coupled with a Cu salt is involved in oxidation of this type, and that the well known redox catalysis of PdXi and CuX is not always operalive[10 ]. The oxidation under anhydrous conditions is unique in terms of the regioselective formation of aldehyde 59 from X-allyl-A -methylbenzamide (58), whereas the use of aqueous DME results in the predominant formation of the methyl ketone 60. Similar results are obtained with allylic acetates and allylic carbonates[102]. The complete reversal of the regioselectivity in PdCli-catalyzed oxidation of alkenes is remarkable. [Pg.30]

With higher alkenes, three kinds of products, namely alkenyl acetates, allylic acetates and dioxygenated products are obtained[142]. The reaction of propylene gives two propenyl acetates (119 and 120) and allyl acetate (121) by the nucleophilic substitution and allylic oxidation. The chemoselective formation of allyl acetate takes place by the gas-phase reaction with the supported Pd(II) and Cu(II) catalyst. Allyl acetate (121) is produced commercially by this method[143]. Methallyl acetate (122) and 2-methylene-1,3-diacetoxypropane (123) are obtained in good yields by the gas-phase oxidation of isobutylene with the supported Pd catalyst[144]. [Pg.38]

Indene derivatives 264a and 264b are formed by the intramolecular reaction of 3-methyl-3-phenyl-l-butene (263a) and 3,3,3-triphenylpropylene (263b) [237]. Two phenyl groups are introduced into the /3-substituted -methylstyrene 265 to form the /3-substituted /3-diphenylmethylstyrene 267 via 266 in one step[238]. Allyl acetate reacts with benzene to give 3-phenylcinnamaldehyde (269) by acyl—O bond fission. The primary product 268 was obtained in a trace amount[239]. [Pg.56]

It is possible to prepare 1-acetoxy-4-chloro-2-alkenes from conjugated dienes with high selectivity. In the presence of stoichiometric amounts of LiOAc and LiCl, l-acetoxy-4-chloro-2-hutene (358) is obtained from butadiene[307], and cw-l-acetoxy-4-chloro-2-cyclohexene (360) is obtained from 1.3-cyclohexa-diene with 99% selectivity[308]. Neither the 1.4-dichloride nor 1.4-diacetate is formed. Good stereocontrol is also observed with acyclic diene.s[309]. The chloride and acetoxy groups have different reactivities. The Pd-catalyzed selective displacement of the chloride in 358 with diethylamine gives 359 without attacking allylic acetate, and the chloride in 360 is displaced with malonate with retention of the stereochemistry to give 361, while the uncatalyzed reaction affords the inversion product 362. [Pg.69]

Numerous applications have been reported. A derivative of the (alkyn-1-yl)nucleosides 295. which have anticancer and antiviral activities, has been synthesized by this reaction. They are also used as chain-terminating nucleosides for DN.A. sequencing[l98,199]. In this reaction, use of DMF as the solvent is most important for successful operation[200]. Only the alkenyl bromide moiety in 2-bromo-3-aceto.xycycloheptene (296) reacts with alkynes without attacking the allylic acetate moiety[201]. [Pg.169]

Allylic acetates are widely used. The oxidative addition of allylic acetates to Pd(0) is reversible, and their reaction must be carried out in the presence of bases. An important improvement in 7r-allylpalladium chemistry has been achieved by the introduction of allylic carbonates. Carbonates are highly reactive. More importantly, their reactions can be carried out under neutral con-ditions[13,14]. Also reactions of allylic carbamates[14], allyl aryl ethers[6,15], and vinyl epoxides[16,17] proceed under neutral conditions without addition of bases. [Pg.292]

The reaction of phenylzinc reagent proceeds with opposite stereochemistry, namely by retention of configuration at the final step via transmetallation. Both the (S)-( )- and (i )-(Z)-allylic acetates 4 and 9 afford the (/ )-( )-phe-nylated product II by overall inversion[23]. [Pg.294]

Based on the above-mentioned stereochemistry of the allylation reactions, nucleophiles have been classified into Nu (overall retention group) and Nu (overall inversion group) by the following experiments with the cyclic exo- and ent/n-acetales 12 and 13[25], No Pd-catalyzed reaction takes place with the exo-allylic acetate 12, because attack of Pd(0) from the rear side to form Tr-allyl-palladium is sterically difficult. On the other hand, smooth 7r-allylpalladium complex formation should take place with the endo-sWyWc acetate 13. The Nu -type nucleophiles must attack the 7r-allylic ligand from the endo side 14, namely tram to the exo-oriented Pd, but this is difficult. On the other hand, the attack of the Nu -type nucleophiles is directed to the Pd. and subsequent reductive elimination affords the exo products 15. Thus the allylation reaction of 13 takes place with the Nu nucleophiles (PhZnCl, formate, indenide anion) and no reaction with Nu nucleophiles (malonate. secondary amines, LiP(S)Ph2, cyclopentadienide anion). [Pg.294]

As supporting evidence, rapid isomerization of the ds- and maui-Tr-allylpal-ladium complexes 27 and 28 is catalyzed by Pd(Ph3P)4 in THF even at -15 C to give a 45 55 equilibrium mixture from either 27 or 28[29-31].. Actually, in the intramolecular reaction of soft nucleophiles of 29 and 30, a trans-ds mi.xttire (31 and 32) (1 1) was obtained from /raiw-allylic acetate 29. On the... [Pg.295]

Allylation under basic conditions. Allylation can be carried out under basic conditions with allylic acetates and phosphates, and under neutral conditions with carbonates and vinyloxiranes. The allylations under neutral conditions are treated separately in Section 2.2.2.1 from those under basic conditions. However, in some cases, allylations of the same substrates are carried out under both basic and neutral conditions to give similar results. These reactions are treated together in this section for convenience. Allylic acetates are widely used for Pd-catalyzed allylation in the presence of bases tertiary amines or NaH are commonly used[6,7,4l]. As a base, basic alumina or ICF on alumina is conveniently used, because it is easy to remove by filtration after the reaction[42]. Allyl phosphates are more reactive than acetates. The allylation with 40 proceeds stepwise. At first allylic phosphate reacts with malonate and then allylic acetate reacts with amine to give 41(43]. [Pg.298]

The intramolecular allylation of soft carbon nucleophiles with allylic acetates as a good cyclization method has been extensively applied to syntheses of various three, four, five and six-membered rings, and medium and macrocyclic compounds[44]. Only a few typical examples of the cyclizations are treated among numerous applications. [Pg.299]

Examples of four-membered ring formation are rare. The cyclization of the cyclic allylic acetate 42 afforded a 2 1 mixture of the four-membered ring compound 43 and the six-membered ring compound 44[45]. [Pg.299]

Simple esters cannot be allylated with allyl acetates, but the Schiff base 109 derived from o -amino acid esters such as glycine or alanine is allylated with allyl acetate. In this way. the o-allyl-a-amino acid 110 can be prepared after hydrolysis[34]. The Q-allyl-o-aminophosphonate 112 is prepared by allylation of the Schiff base 111 of diethyl aminomethylphosphonates. [35,36]. Asymmetric synthesis in this reaction using the (+ )-A, jV-dicyclohex-ylsulfamoylisobornyl alcohol ester of glycine and DIOP as a chiral ligand achieved 99% ec[72]. [Pg.306]

The allyl-substituted cyclopentadiene 122 was prepared by the reaction of cyclopentadiene anion with allylic acetates[83], Allyl chloride reacts with carbon nucleophiles without Pd catalyst, but sometimes Pd catalyst accelerates the reaction of allylic chlorides and gives higher selectivity. As an example, allylation of the anion of 6,6-dimethylfulvene 123 with allyl chloride proceeded regioselectively at the methyl group, yielding 124[84]. The uncatalyzed reaction was not selective. [Pg.308]

Aldehydes take part in the cycloaddition to give the methylenetetrahydrofuran 178 by the co-catalysis of Pd and Sn compounds[115]. A similar product 180 is obtained by the reaction of the allyl acetate 179, which has a tributyltin group instead of a TMS group, with aldehydesfl 16]. The pyrrolidine derivative 182 is formed by the addition of the tosylimine 181 to 154[117]. [Pg.314]

Wylation under neutral conditions. Reactions which proceed under neutral conditions are highly desirable, Allylation with allylic acetates and phosphates is carried out under basic conditions. Almost no reaction of these allylic Compounds takes place in the absence of bases. The useful allylation under neutral conditions is possible with some allylic compounds. Among them, allylic carbonates 218 are the most reactive and their reactions proceed under neutral conditions[13,14,134], In the mechanism shown, the oxidative addition of the allyl carbonates 218 is followed by decarboxylation as an irreversible process to afford the 7r-allylpalladium alkoxide 219. and the generated alkoxide is sufficiently basic to pick up a proton from active methylene compounds, yielding 220. This in situ formation of the alkoxide. which is a... [Pg.319]

Intramolecular amination with allylic acetates is used for the synthesis of cyclic alkaloids 175]. Cyclization of 293 affords the six-membered ring compound 294 rather than a four-membered ring. The reaction is particularly... [Pg.329]

Carbamates are allylated in the presenee of strong bases in DMSO or HMPA[197], Phthalimide (320) and succimide are allylated with the allyl-isoureu 321 at room temperature or the allylic acetate 322 at 100 C[I98.I99], Di-/-butyl iminodicarbonate is used as a nitrogen nucleophile[200]. [Pg.333]

Phenols arc highly reactive 0-nucleophiles and allylated easily with allylic carbonates under neutral conditions. EWGs on phenols favor the reac-tion[213]. Allylic acetates are used for the allylation of phenol in the presence of KF-alumina as a base[214]. [Pg.337]

Carbon-phosphorus bonds are formed by the allylation of various phosphorus compounds. The allyldiphenylphosphine sulfide 346 is formed by the reaction of allylic acetates with lithium diphenylthiophosphide 343[215]. [Pg.337]

Various S-nucleophiles are allylated. Allylic acetates or carbonates react with thiols or trimethylsilyl sulfide (353) to give the allylic sulfide 354[222], Allyl sulfides are prepared by Pd-catalyzed allylic rearrangement of the dithio-carbonate 355 with elimination of COS under mild conditions. The benzyl alkyl sulfide 357 can be prepared from the dithiocarbonate 356 at 65 C[223,224], The allyl aryl sufide 359 is prepared by the reaction of an allylic carbonate with the aromatic thiol 358 by use of dppb under neutral condi-tions[225]. The O-allyl phosphoro- or phosphonothionate 360 undergoes the thiono thiolo allylic rearrangement (from 0-allyl to S -allyl rearrangement) to afford 361 and 362 at 130 C[226],... [Pg.338]

It is known that tr-allylpalladium acetate is converted into allyl acetate by reductive elimination when it is treated with CO[242,243]. For this reason, the carbonylation of allylic acetates themselves is difficult. The allylic acetate 386 is carbonylated in the presence of NaBr (20-50 mol%) under severe conditions, probably via allylic bromides[244]. However, the carbonylation of 5-phenyl-2,4-pentadienyl acetate (387) was carried out in the presence of EtiN without using NaBr at 100 °C to yield methyl 6-phenyl-3,5-hexadienoate (388)[245J. The dicarbonylation of l,4-diacetoxy-2-butene to form the 3-hexenedioate also proceeds by using tetrabutylphosphonium chloride as a ligand in 49% yield[246]. [Pg.341]

Unusual cyclocarbonylation of allylic acetates proceeds in the presence of acetic anhydride and an amine to afford acetates of phenol derivatives. The cinnamyl acetate derivative 408 undergoes carbonylation and Friedel-Crafts-type cyclization to form the a-naphthyl acetate 410 under severe condi-tions[263,264]. The reaction proceeds at 140-170 under 50-70 atm of CO in the presence of acetic anhydride and Et N. Addition of acetic anhydride is essential for the cyclization. The key step seems to be the Friedel-Crafts-type cyclization of an acylpalladium complex as shown by 409. When MeOH is added instead of acetic anhydride, /3,7-unsaturated esters such as 388 are... [Pg.344]

Perfluoroalkylzinc iodides, prepared in situ from iodides and ultrasonically dispersed Zn, are coupled with allylic halides via an allylic rearrangement[271]. The Pd-catalyzed homocoupling of allylic acetate in the presence of Zn to give a mixture of regioisomers 416 and 417 may proceed via in situ formation of allylzinc species[272,273]. [Pg.346]

Organoboranes are reactive compounds for cross-coupling[277]. The synthesis of humulene (83) by the intramolecular cross-coupling of allylic bromide with alkenylborane is an example[278]. The reaction of vinyiborane with vinyl-oxirane (425) affords the homoallylic alcohol 426 by 1,2-addition as main products and the allylic alcohol 427 by 1,4-addition as a minor product[279]. Two phenyl groups in sodium tetraphenylborate (428) are used for the coupling with allylic acetate[280] or allyl chloride[33,28l]. [Pg.347]

It was claimed that the Z-form of the allylic acetate 430 was retained in homoallylic ketone 431 obtained by reaction with the potassium enolate of 3-vinylcyclopentanone (429), after treatment with triethylborane[282]. Usually this is not possible. The reaction of a (Z)-allylic chloride with an alkenylaluminum reagent to give 1,4-dienes proceeds with retention of the stereochemistry to a considerable extent when it is carried out at -70 C[283]. [Pg.348]

Allylic acetates react with ketene silyl acetals. In this reaction, in addition to the allylated ester 468, the cyclopropane derivative 469. which is formed by the use of bidentate ligands, is obtained[303]. Formation of a cyclopropane derivative 471 has been observed by the stoichiometric reaction of the 7r-allylpal-... [Pg.352]

The allylstannane 474 is prepared by the reaction of allylic acetates or phosphates with tributyltin chloride and Sml2[286,308] or electroreduction[309]. Bu-iSnAlEt2 prepared in situ is used for the preparation of the allylstannane 475. These reactions correspond to inversion of an allyl cation to an allyl anion[3l0. 311], The reaction has been applied to the reductive cyclization of the alkenyl bromide in 476 with the allylic acetate to yield 477[312]. Intramolecular coupling of the allylic acetate in 478 with aryl bromide proceeds using BuiSnAlEti (479) by in situ formation of the allylstannane 480 and its reaction with the aryl bromide via transmetallation. (Another mechanistic possibility is the formation of an arylstannane and its coupling with allylic... [Pg.353]


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1- Substituted 2-propenyl acetate, allylic alkylations

2- allyl acetate allylation

2- allyl acetate allylation

2- allyl acetate, Tsuji-Trost

2- allyl acetate, Tsuji-Trost reaction

3- Phenylpropanal, from allyl alcohol and phenylpalladium acetate

4-Allyl-2-methoxyphenol Acetate

ALLYL ACETATE.29(Vol

Acetal allylation

Acetal allylation

Acetals Hosomi-Sakurai allylation

Acetals allyl silane addition

Acetals allylations

Acetals allylations

Acetals allylic silanes

Acetals allylic stannanes

Acetals asymmetric allylation

Acetals, allylic reaction with organocopper compounds

Acetate allyl, reaction with diketones

Acetate reactions allylic elimination

Acetate reactions asymmetric allylation

Acetates allylic, coupling with carboxylic acids

Acetic acid allyl ester

Acetoxylation of Alkenes to Vinyl or Allyl Acetates

Acyclic acetals, allylation

Alkenes allylic acetoxylations, palladium acetate

Alkenes allylic alcohols, palladium acetate

Alkenes cyclic allylic acetates

Alkenes from allylic acetates

Allenes allyl acetate

Allyl Phenoxy Acetate

Allyl Phenoxy Acetate (new)

Allyl acetal

Allyl acetal hydroformylation

Allyl acetate

Allyl acetate

Allyl acetate bulk polymerization

Allyl acetate cationic polymerization

Allyl acetate emulsion polymerization

Allyl acetate polymerization

Allyl acetate polymerization, chain transfer

Allyl acetate polymerization, chain transfer monomer

Allyl acetate solution polymerization

Allyl acetate, 1,4-butanediol from

Allyl acetate, 2- cycloaddition

Allyl acetate, 2- cycloaddition reactions

Allyl acetate, formation

Allyl acetate, hydroformylation

Allyl acetate, ozone reactions with

Allyl acetate, reaction

Allyl acetate, telomerization

Allyl acetates acetylation

Allyl acetates allylic transposition

Allyl acetates arylation

Allyl acetates carbonylation

Allyl acetates conditions

Allyl acetates cyclic ether synthesis

Allyl acetates cyclization reactions

Allyl acetates dicarboxylation

Allyl acetates electrolysis

Allyl acetates hydrogenolysis

Allyl acetates isomerization

Allyl acetates oxidation

Allyl acetates palladium catalysis

Allyl acetates palladium-catalyzed

Allyl acetates production

Allyl acetates reactions with carbonyl compounds

Allyl acetates rearrangements

Allyl acetates reduction

Allyl acetates substituted

Allyl acetates synthesis

Allyl acetates transition metal catalyzed reactions

Allyl acetates via alcohols

Allyl bromides Allylic acetates

Allyl trimethylsilyl ketene acetal

Allylation of Aldehydes, Ketones, and Acetals

Allylation with allyl acetate

Allylations Morita-Baylis-Hillman acetate

Allylations acetals, allyltrimethylsilane

Allylic Acetal Substrates

Allylic acetals

Allylic acetals

Allylic acetate, also

Allylic acetates acetate

Allylic acetates acetate

Allylic acetates reactions

Allylic acetates reactions with carbonyl compounds

Allylic acetates samarium diiodide

Allylic acetates, decarboxylative eliminations

Allylic allyl acetates

Allylic aminations, crotyl acetate/piperidine

Allylic derivatives carbonylation, acetate compounds

Allylic ketene acetal

Allylic ketene acetal 3,3] sigmatropic rearrangement

Allylic oxidations alkenes, manganese acetate

Asymmetric allylation 1,3-diphenylpropenyl acetate

Asymmetric allylation of aldehydes, ketones, and acetals

Asymmetric allylic alkylations -1,3-diphenylprop-2-enyl acetate

Bicyclic allylic acetate

Borylations allylic acetates

Bromoacetaldehyde allyl acetals

Catalytic cycle, allyl acetates

Condensation reactions allylic acetates

Coordinating functional groups allylic acetate

Crotyl acetate, allylic amination

Cyclic acetals, allylation

Cyclic acetates, asymmetric allylic alkylations

Cyclic allylic acetates, alkylation

DKR of Allylic Acetates

Decarboxylation, allylic acetates

Decarboxylation, allylic acetates reaction

Diphenylallyl acetate, asymmetric allylic

Diphenylallyl acetate, asymmetric allylic alkylation

Drimenyl acetate allylic oxidation

Elimination from allylic acetates

F Allyl acetate

Geranyl acetate allylic oxidation

Geranyl acetate allylic oxidative rearrangement

Grignard reagents allylic acetals

Homoallyl tandem acetalization-allylation

Hydrogenolysis of allyl acetates

Hydrogenolysis of allylic acetates

Industrial processes allyl acetate

Mercuric Acetate allyl alcohol with

Mercury acetate allylic oxidation

Metal acetates allylic oxidation

Natural product synthesis allyl acetate

Neryl acetate allylic oxidation

Nucleophilic displacement of allylic acetate

Nucleophilic racemic allyl acetates

Organopalladium compounds allylic acetate

Oxidation of allyl acetate

Oxidative of allyl acetate

Ozone with allyl acetate

P-Diesters reaction with allylic acetate

Palladium acetate allylations

Palladium acetate allylic oxidation

Propylene allyl acetate from

Radical Cyclization of -lodo Allylic Acetals with EtMgBr

Radical allylic acetates

Reaction with allylic acetates

Rearrangement of allylic acetals

Reduction of Allyl Acetates

Resolutions allyl acetates

Rhodium acetate allylic oxidation

Silver acetate allylic oxidation

Sodium azide, reaction with allylic acetates

Stannylene acetals 0-allylation

Stille coupling 2- allyl acetate

Substitution reactions allyl acetates, resolution

Trost cyclization of allylic acetate

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