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Allyl carbonates allylation

Allylic carbocations are carbocations in which the positive charge is on an allylic carbon. Allyl cation is the simplest allylic carbocation. [Pg.391]

Nucleophilic Substitution at an Allylic Carbon. Allylic Rearrangements... [Pg.327]

The relative reactivity of the derivatives follows the trend allyl carbonate > allyl phosphate > allyl acetate (see Equations 20.5-20.7)." This difference in reactivity allows for chemoselective substitutions of one allylic alcohol derivative over another. Other allylic electrophiles, such as allylic sulfonates, which undergo cleavage of the carbon-sulfur bond, allylic nitro compounds, which undergo cleavage of the C-N bond, - and allylic... [Pg.969]

Allyl esters of saturated acids have been extensively studied because of the potential application as a silane coupling agent. The addition of silicon hydrides to allyl chloroformate, allyl carbonate, allyl formate, and allyl acetate occurs selectively at the C=C bond according to Farmer s (anti-Markownikov) rule, giving the appropriate /3-adducts although propene and acetoxysilane are also formed as by-products ... [Pg.1289]

Surprisingly, even allyl alcohol undergoes the allylation of aldehydes in the presence of 2 mol % of PdCl2(PhCN)2 and 3 equiv of tin(n) dichloride in DMI (Scheme 7)3 ° " The reaction is compatible with aUcyl bromide, aryl bromide, and allyl acetate functionality. The reactivity order of allylic system is allylic carbonate > allylic alcohol > allylic acetate. Un-symmetrical allylic alcohols regioselectively undergo nucleophilic addition at the allylic termini with the highest number of substituent. Generally, anh-isomers are produced preferentially over iyn-isomers. [Pg.284]

A white solid, m.p. 178 C. Primarily of interest as a brominaling agent which will replace activated hydrogen atoms in benzylic or allylic positions, and also those on a carbon atom a to a carbonyl group. Activating influences can produce nuclear substitution in a benzene ring and certain heterocyclic compounds also used in the oxidation of secondary alcohols to ketones. [Pg.69]

The dimension of the matrix is the number of atoms in the n conjugated system. Let us take the three-carbon system allyl as our next step. Concentrate on the end... [Pg.189]

We have already obtained solutions for localized ground-state ethylene leading to the energy F = 2"z -h 2(3, In looking at allyl. the next more complicated case, we can regard it as an isolated double bond between two carbons to which an. y/z carbon is attached. [Pg.215]

In the Huckel theory of simple hydrocarbons, one assumes that the election density on a carbon atom and the order of bonds connected to it (which is an election density between atoms) are uninfluenced by election densities and bond orders elsewhere in the molecule. In PPP-SCF theory, exchange and electrostatic repulsion among electrons are specifically built into the method by including exchange and electrostatic terms in the elements of the F matrix. A simple example is the 1,3 element of the matrix for the allyl anion, which is zero in the Huckel method but is 1.44 eV due to election repulsion between the 1 and 3 carbon atoms in one implementation of the PPP-SCF method. [Pg.250]

Let us illustrate the meaning of F by the example of carbon atom 1 in the linear, three-carbon allyl anion C3Hg. There are two carbon atoms other than Ci, one adjacent and the other nonadjacent. Equation (8-44) has three temis, one for each carbon atom... [Pg.250]

Note that agreement with Pariser and Parr s empirical value is better for Y13 than for Yn ) Use Salem s values to calculate election densities on the three carbon atoms of the allyl anion for one iteration beyond the initial Huckel values, as was done in Exercise 8.9.1. Comment on the results you get, as to the qualitative picture of the anion, the influence of election repulsion on the charge densities, and agreement or lack of agreement with the results already obtained with the Pariser and Parr parameters. [Pg.261]

Allyl Bromide. Introduce into a 1-litre three-necked flask 250 g. (169 ml.) of 48 per cent, hydrobromic acid and then 75 g. (40-5 ml.) of concentrated sulphuric acid in portions, with shaking Anally add 58 g. (68 ml.) of pure allyl alcohol (Section 111,140). Fit the flask with a separatory funnel, a mechanical stirrer and an efficient condenser (preferably of the double surface type) set for downward distillation connect the flask to the condenser by a wide (6-8 mm.) bent tube. Place 75 g. (40 5 ml.) of concentrated sulphuric acid in the separatory funnel, set the stirrer in motion, and allow the acid to flow slowly into the warm solution. The allyl bromide will distil over (< 30 minutes). Wash the distillate with 5 per cent, sodium carbonate solution, followed by water, dry over anhydrous calcium chloride, and distil from a Claisen flask with a fractionating side arm or through a short column. The yield of allyl bromide, b.p. 69-72°, is 112 g. There is a small high-boiling fraction containing propylene dibromide. [Pg.280]

Treat the combined distiUates of b.p. 195-260° with anhydrous potassium carbonate to neutralise the Uttle formic acid present and to salt out the allyl alcohol. Distil the latter through a fractionating column and collect the fraction of b.p, up to 99° separately this weighs 210 g, and consists of 70 per cent, allyl alcohol. To obtain anli5 dious allyl alcohol, use either of the following procedures —... [Pg.459]

Review Problem 2 This allyl bromide is an important intermediate in the synthesis of terpenes (including many flavouring and perfumery compounds), as the five carbon fi agment occurs widely in nature. How would you make it ... [Pg.12]

You have already seen that a carbon-heteroatom bond is easy to make, since we used such bonds as natural places for disconnections (frames 234 ft). It is good strategy therefore to make a carbon-heteroatom bond and then to transform it into a carbon-earbon bond. The Claisen rearrangement is one way to do this an ortho allyl phenol (B) made from an allyl ether (A) ... [Pg.104]

Allyl halides do however give us good yields of alkylation at carbon ... [Pg.106]

The basic premise for making bromosafrole has been to mix sa-frole with Hydrobromic Acid (a.k.a. hydrogen bromide, HBr). That s it. The HBr does what is called a Markovnikov addition reaction whereby the HBr sees the allyl double bond of safrole and preferentially attaches its hydrogen to the gamma carbon and its bromine to the middle beta carbon (don t ask). [Pg.143]

Benzylic anions, ArCHj, are of little importance in the construction of carbon skeletons, and allylic anions, R C—CR—CR", are discussed in the d -synthons section below. [Pg.14]

Substituted epoxides are attacked by organocopper reagents at the least hindered carbon atom and form alcohols (C.R. Johnson, 1973A). With a, 9-unsaturated epoxides tram-allylic alcohols are produced selectively by 1,4-addltion (W. Carruthers, 1973 G.H. Posner, 1972). [Pg.21]

Aryl and vinylic bromides and iodides react with the least substituted and most electrophilic carbon atoms of activated olefins, e.g., styrenes, allylic alcohols, a,p-unsaturated esters and nitriles. [Pg.42]

Alkenes in (alkene)dicarbonyl(T -cyclopentadienyl)iron(l+) cations react with carbon nucleophiles to form new C —C bonds (M. Rosenblum, 1974 A.J. Pearson, 1987). Tricarbon-yi(ri -cycIohexadienyI)iron(l-h) cations, prepared from the T] -l,3-cyclohexadiene complexes by hydride abstraction with tritylium cations, react similarly to give 5-substituted 1,3-cyclo-hexadienes, and neutral tricarbonyl(n -l,3-cyciohexadiene)iron complexes can be coupled with olefins by hydrogen transfer at > 140°C. These reactions proceed regio- and stereospecifically in the successive cyanide addition and spirocyclization at an optically pure N-allyl-N-phenyl-1,3-cyclohexadiene-l-carboxamide iron complex (A.J. Pearson, 1989). [Pg.44]

Catalytic hydrogenation is mostly used to convert C—C triple bonds into C C double bonds and alkenes into alkanes or to replace allylic or benzylic hetero atoms by hydrogen (H. Kropf, 1980). Simple theory postulates cis- or syn-addition of hydrogen to the C—C triple or double bond with heterogeneous (R. L. Augustine, 1965, 1968, 1976 P. N. Rylander, 1979) and homogeneous (A. J. Birch, 1976) catalysts. Sulfur functions can be removed with reducing metals, e. g. with Raney nickel (G. R. Pettit, 1962 A). Heteroaromatic systems may be reduced with the aid of ruthenium on carbon. [Pg.96]

In all cases examined the ( )-isomers of the allylic alcohols reacted satisfactorily in the asymmetric epoxidation step, whereas the epoxidations of the (Z)-isomers were intolerably slow or nonstereoselective. The eryfhro-isomers obtained from the ( )-allylic alcohols may, however, be epimerized in 95% yield to the more stable tlireo-isomers by treatment of the acetonides with potassium carbonate (6a). The competitive -elimination is suppressed by the acetonide protecting group because it maintains orthogonality between the enolate 7i-system and the 8-alkoxy group (cf the Baldwin rules, p. 316). [Pg.265]

Formation of a Tr-allylpalladium complex 29 takes place by the oxidative addition of allylic compounds, typically allylic esters, to Pd(0). The rr-allylpal-ladium complex is a resonance form of ir-allylpalladium and a coordinated tt-bond. TT-Allylpalladium complex formation involves inversion of stereochemistry, and the attack of the soft carbon nucleophile on the 7r-allylpalladium complex is also inversion, resulting in overall retention of the stereochemistry. On the other hand, the attack of hard carbon nucleophiles is retention, and hence Overall inversion takes place by the reaction of the hard carbon nucleophiles. [Pg.15]

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]

TT-Aliylpalladium chloride reacts with a soft carbon nucleophile such as mal-onate and acetoacetate in DMSO as a coordinating solvent, and facile carbon-carbon bond formation takes place[l2,265], This reaction constitutes the basis of both stoichiometric and catalytic 7r-allylpalladium chemistry. Depending on the way in which 7r-allylpalladium complexes are prepared, the reaction becomes stoichiometric or catalytic. Preparation of the 7r-allylpalladium complexes 298 by the oxidative addition of Pd(0) to various allylic compounds (esters, carbonates etc.), and their reactions with nucleophiles, are catalytic, because Pd(0) is regenerated after the reaction with the nucleophile, and reacts again with allylic compounds. These catalytic reactions are treated in Chapter 4, Section 2. On the other hand, the preparation of the 7r-allyl complexes 299 from alkenes requires Pd(II) salts. The subsequent reaction with the nucleophile forms Pd(0). The whole process consumes Pd(ll), and ends as a stoichiometric process, because the in situ reoxidation of Pd(0) is hardly attainable. These stoichiometric reactions are treated in this section. [Pg.61]

The enamine 315 as a carbon nucleophile reacts with 7r-allylpalladium complexes to give allyl ketones after hydrolysis[265],... [Pg.63]

Interestingly, some nucleophiles attack the central carbon of the 7r-allyl system to form a palladacyclobutane 316 and its reductive elimination gives... [Pg.63]

Hard carbon nucleophiles of organometallic compounds react with 7r-allyl-palladium complexes. A steroidal side-chain is introduced regio- and stereo-selectively by the reaction of the steroidal 7T-allylpalladium complex 319 with the alkenylzirconium compound 320[283]. [Pg.64]

When butadiene is treated with PdCU the l-chloromethyl-7r-allylpalladium complex 336 (X = Cl) is formed by the chloropalladation. In the presence of nucleophiles, the substituted 7r-methallylpalladium complex 336 (X = nucleophile) is formed(296-299]. In this way, the nucleophile can be introduced at the terminal carbon of conjugated diene systems. For example, a methoxy group is introduced at the terminal carbon of 3,7-dimethyl-I,3,6-octatriene to give 337 as expected, whereas myrcene (338) is converted into the tr-allyl complex 339 after the cyclization[288]. [Pg.66]

The wM-diacetate 363 can be transformed into either enantiomer of the 4-substituted 2-cyclohexen-l-ol 364 via the enzymatic hydrolysis. By changing the relative reactivity of the allylic leaving groups (acetate and the more reactive carbonate), either enantiomer of 4-substituted cyclohexenyl acetate is accessible by choice. Then the enantioselective synthesis of (7 )- and (S)-5-substituted 1,3-cyclohexadienes 365 and 367 can be achieved. The Pd(II)-cat-alyzed acetoxylactonization of the diene acids affords the lactones 366 and 368 of different stereochemistry[310]. The tropane alkaloid skeletons 370 and 371 have been constructed based on this chemoselective Pd-catalyzed reactions of 6-benzyloxy-l,3-cycloheptadiene (369)[311]. [Pg.70]

Two monomeric and dimeric 2-substituied 7r-allylic complexes (548 and 549) are obtained by treatment of allene with PdCl2(PhCN)2. They are formed by the nucleophilic attack at the central carbon of allene[493, 494],... [Pg.102]

Several Pd(0) complexes are effective catalysts of a variety of reactions, and these catalytic reactions are particularly useful because they are catalytic without adding other oxidants and proceed with catalytic amounts of expensive Pd compounds. These reactions are treated in this chapter. Among many substrates used for the catalytic reactions, organic halides and allylic esters are two of the most widely used, and they undergo facile oxidative additions to Pd(0) to form complexes which have o-Pd—C bonds. These intermediate complexes undergo several different transformations. Regeneration of Pd(0) species in the final step makes the reaction catalytic. These reactions of organic halides except allylic halides are treated in Section 1 and the reactions of various allylic compounds are surveyed in Section 2. Catalytic reactions of dienes, alkynes. and alkenes are treated in other sections. These reactions offer unique methods for carbon-carbon bond formation, which are impossible by other means. [Pg.125]

When allylic alcohols are used as an alkene component in the reaction with aryl halides, elimination of /3-hydrogen takes place from the oxygen-bearing carbon, and aldehydes or ketones are obtained, rather than y-arylated allylic alcohoIs[87,88]. The reaction of allyl alcohol with bromobenzene affords dihydrocinnamaldehyde. The reaction of methallyl alcohol (96) with aryl halides is a good synthetic method for dihydro-2-methylcinnamaldehyde (97). [Pg.142]

Aryl or alkenyl halides attack the central carbon of the allene system in the 2,3-butadien-l-ol 120 to form the 7r-allyl intermediate 121, which undergoes elimination reaction to afford the o,/3-unsaturated ketone 122 or aldehyde. The reaction proceeds smoothly in DMSO using dppe as a ligandflOl]. [Pg.145]

When allene derivatives are treated with aryl halides in the presence of Pd(0), the aryl group is introduced to the central carbon by insertion of one of the allenic bonds to form the 7r-allylpalladium intermediate 271, which is attacked further by amine to give the allylic amine 272. A good ligand for the reaction is dppe[182]. Intramolecular reaction of the 7-aminoallene 273 affords the pyrrolidine derivative 274[183]. [Pg.166]

Allenes also react with aryl and alkenyl halides, or triflates, and the 7r-allyl-palladium intermediates are trapped with carbon nucleophiles. The formation of 283 with malonate is an example[186]. The steroid skeleton 287 has been constructed by two-step reactions of allene with the enol trillate 284, followed by trapping with 2-methyl-l,3-cyclopentanedione (285) to give 286[187]. The inter- and intramolecular reactions of dimethyl 2,3-butenylmalonate (288) with iodobenzene afford the 3-cyclopentenedicarboxylate 289 as a main product) 188]. [Pg.167]


See other pages where Allyl carbonates allylation is mentioned: [Pg.384]    [Pg.199]    [Pg.1127]    [Pg.1127]    [Pg.211]    [Pg.23]    [Pg.353]    [Pg.193]    [Pg.301]    [Pg.459]    [Pg.460]    [Pg.252]    [Pg.253]    [Pg.6]    [Pg.122]    [Pg.299]    [Pg.38]    [Pg.62]    [Pg.62]   
See also in sourсe #XX -- [ Pg.592 ]




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1,3-disubstituted allylic carbonate

Acemoglu and Jonathan M. J. Williams 3 Palladium-Catalyzed Allylation with Allyl Carbonates

Alcohols allylic carbonates, protection using

Aldehyde From allylic alcohol (one carbon

Alkanes, carbon-sulfur bond allylation

Alkenyl allyl carbonates

Allyl Diglycol Carbonate (CR

Allyl alcohol reaction with carbon tetrachloride

Allyl carbon centers, nucleophilic substitution

Allyl carbonate

Allyl carbonate

Allyl carbonates 1.3- sigmatropic rearrangements

Allyl carbonates 2.3.3- trisubstituted

Allyl carbonates 3£)-substituted

Allyl carbonates alcohol protection

Allyl carbonates asymmetric epoxidation

Allyl carbonates carbonylation

Allyl carbonates cleavage

Allyl carbonates conjugated diene preparation

Allyl carbonates copper-catalyzed

Allyl carbonates cyclization

Allyl carbonates deprotection

Allyl carbonates deracemization

Allyl carbonates diastereoselectivity

Allyl carbonates epimerization

Allyl carbonates epoxidation

Allyl carbonates homogeneous hydrogenation

Allyl carbonates hydroformylation

Allyl carbonates hydrogenolysis

Allyl carbonates hydroxylation

Allyl carbonates nitrile synthesis

Allyl carbonates optically active

Allyl carbonates oxidation

Allyl carbonates oxidative rearrangement

Allyl carbonates palladium complexes

Allyl carbonates palladium enolates

Allyl carbonates radical cyclization

Allyl carbonates rearrangement

Allyl carbonates reduction

Allyl carbonates solid support

Allyl carbonates specificity

Allyl carbonates stereoselective

Allyl carbonates substitutions

Allyl carbonates synthesis

Allyl carbonates tertiary

Allyl carbonates transformation reactions

Allyl carbonates transition metal catalyzed reactions

Allyl carbonates transmetallation

Allyl carbonates vinylation

Allyl carbonates, 2- cycloaddition

Allyl carbonates, 2- cycloaddition palladium catalysis

Allyl carbonates, methylcycloaddition

Allyl carbonates, methylcycloaddition 4 + 3] cycloaddition reactions

Allyl carbonates, methylcycloaddition palladium catalysis

Allyl carbonates, pyrolysis

Allyl complexes reaction with carbon dioxide

Allyl diglycol carbonate

Allyl enol carbonates

Allyl enol carbonates palladium-catalyzed

Allyl enol carbonates, Tsuji

Allyl enol carbonates, Tsuji allylation

Allyl enol carbonates, decarboxylation

Allyl enol carbonates, decarboxylation reactions

Allyl ethyl carbonate

Allyl methyl carbonate

Allyl phenyl carbonate

Allyl-diglycol-carbonate polymer

Allylation carbon nucleophiles

Allylation of Carbon-Nitrogen Double Bonds

Allylation of Soft Carbon Nucleophiles

Allylation of Stabilized Carbon Nucleophiles

Allylations electrophilic carbon moieties

Allylic Organometallic Reagents Useful Three-Carbon Nucleophiles

Allylic amination carbon-nitrogen bond formation

Allylic carbon

Allylic carbon

Allylic carbon bromination

Allylic carbon definition

Allylic carbon halogenation

Allylic carbon hydroxylation

Allylic carbon oxidation

Allylic carbon product mixtures

Allylic carbon radical halogenation

Allylic carbon reactions

Allylic carbon selective bromination

Allylic carbon, nucleophilic

Allylic carbon, nucleophilic displacement

Allylic carbonates

Allylic carbonates and carbamates

Allylic carbonates, coupling reactions

Allylic carbonates, iodolactonization

Allylic carbons, electrochemical oxidation

Allylic cyclic carbonates

Allylic derivatives carbon monoxide reactions

Allylic derivatives carbon nucleophile reactions

Allylic halides with sp3 carbon centers

Allylic substitution carbon nucleophiles

Allylic substitution, Baylis-Hillman carbonates

Allylic with carbon nucleophiles

Aryl zinc reagents, allylic carbonates

Asymmetric allylation, Baylis-Hillman carbonates

Carbamates allyl carbonate reactions

Carbon allyl

Carbon allyl

Carbon allylation

Carbon allylation

Carbon atoms allylic

Carbon monoxide allylic compounds

Carbon monoxide allylic halides

Carbon nucleophiles allyl halides

Carbon nucleophiles allylation reactions

Carbon nucleophiles allylic compounds. Tsuji-Trost reaction

Carbon nucleophiles allylic rearrangement

Carbon-hydrogen bonds allylic, selective bromination

Carbon-oxygen bonds diene conjugation, allylic intermediates

Carbonates 2-aryl allylic

Carbonates, allylic, coupling

Carbonates, allylic, coupling compounds

Carbonates, allylic, coupling enol, alkylation

Carbonates, allylic, coupling from alcohols

Carbonates, allylic, coupling ketones

Carbonates, allylic, coupling metal, with ketones

Carbonates, asymmetric Baylis-Hillman allylic substitution

Coupling reactions of allylic carbonates

Cyclic carbonates, allylation reactions

Cydic allyl carbonates

Diethylene glycol bis-allyl carbonate

Enantioselectivity, coupling with allylic carbonates

Intramolecular reactions Tsuji-Trost reaction, allylation, carbon

Nucleophilic substitution at an allylic carbon

Optically active allyl carbonates, allylic alkylations

Phosphine catalysts carbonates, asymmetric allylic

Quaternary carbon compounds allylic alkylation

Radical Halogenation at an Allylic Carbon

Reactions at an Allylic Carbon Atom

Reactions involving allyl carbonates

Reagents allylic-carbon monoxide reactions

Rearrangement alcohol protection, allylic carbonates

Rearrangement allyl carbonate reactions

Rhodium-Catalyzed Allylic Alkylation Reaction with Stabilized Carbon Nucleophiles

Soft carbon nucleophiles allylic derivatives

Titanium complexes, reaction with carbon allyl

Tsuji-Trost reaction allyl carbonate allylation

Using allyl carbonates

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