Alkene diester

If alkyl groups are attached to the ylide carbon atom, cis-olefins are formed at low temperatures with stereoselectivity up to 98Vo. Sodium bis(trimethylsilyl)amide is a recommended base for this purpose. Electron withdrawing groups at the ylide carbon atom give rise to trans-stereoselectivity. If the carbon atom is connected with a polyene, mixtures of cis- and rrans-alkenes are formed. The trans-olefin is also stereoseiectively produced when phosphonate diester a-carbanions are used, because the elimination of a phosphate ester anion is slow (W.S. Wadsworth, 1977). 

In the carbonylation of trans,trans,cis-CDT, the trans double bond is attacked preferentially to give the monoester 10, and then the diester 11. Attack of the cis double bond to give the triester is slow[15]. Only the C-16 alkene was carbonylated regio- and stereoselectively to give the Ibo-carboxy-late 12 by carbonylation of the C-5 and C-16 unsaturaied steroid[]6]. 

Alkenes (R) react with 0s04 to give two kinds of esters the so-called monoesters 0s02(02R), which are actually dimers, (0s204(02R)2) and diesters 0s0(02R)2 (Figure 1.70) [183],... 

Most researchers currently agree that the hydrido mechanism is more common than the alkoxycarbonyl path in the alkoxycarbonylation of alkenes with palladium systems. However, carbalkoxy complexes are putative intermediates in carbonylation reactions giving succinates and polyketone diesters, with metals like Co, Rh, or Pd.137... 

Another convenient entry to fused cyclobutene-1,2-diesters was via site selective modification of the norbomene rt-bond in Smith s fe-alkene 49, e.g. treatment with 3,6-di(2 -pyridyl)-s-tetrazine 51 followed by DDQ oxidation afforded the cyclobutene-derivative 53 <97AA119>, while direct coupling with 3,5-f> (trifluoromethyl)-l,3,4-oxadiazo]e 54 furnished the tas(cyclobutene-l,2-diester) 55 (Scheme 6) <97SL196>. 

The two alkenes were so similar electronically and sterically, with the ester group too far away to have any affect on the double bond, that there was very little cross-/self-metathesis selectivity. An approximately statistical mixture of ester 13 and diester 14 was isolated. The high yield of the cross-metathesis product 13 obtained is due to the excess of the volatile hex-l-ene used, rather than a good cross-/self-metathesis selectivity. Although not as predominant as in the reactions involving styrene, trans alkenes were still the major products. 

Following the first observations by Heck that Pd(OAc)2 can substitute a hydrogen atom in ethylene by a carbomethoxy group [50], Stille and James have discovered that the [Pd - Cu] couple catalyzes the incorporation of a COOMe group arising from carbon monoxide and methanol [51]. Most of the reactions with an alkene end up with a diester or a methoxyester, copper being used in stoichiometric quantities. Cyclic alkenes give preferentially diesters (Scheme 7). 

Inomata and co-workers later reported that the same [Pd-Cu] system could also, in the presence of oxygen, drive the reaction towards the formation of the monoester with Cu(II) or diester with Cu(I) [52,53]. Other Pd catalyst/oxidant systems have been used for the bisalkoxycarbonylation of alkenes however the formation of by-products in the Pd-reoxidation process decreases ester yields dramatically [54],... 

Scheme 7 An example of the methoxycarbonylation of a cyclic alkene leading to a diester...

A wide range of organic substrates can undergo an oxidative carbonylation reaction. Depending on reaction conditions, alkenes have been converted into -chloroalkanoyl chlorides (oxidative chloro-chlorocarbonylation) [1,2], succinic diesters (oxidative dialkoxycarbonylation) [3-20], a,/J-unsaturated esters [21,22] (oxidative monoalkoxycarbonylation), or /J-alkoxyalkanoic esters [11] (oxidative alkoxy-alkoxycarbonylation), according to Eqs. 10-13. 

Products. The work of Wagner (42,43) and Boeseken (44) established that the oxidation of alkenes under alkaline conditions results in a syn-addition of two hydroxyl groups. In order to account for this observation, Wagner suggested that the reaction must proceed by way of an intermediate cyclic manganate(V) diester, 1, as in equation 3. 

The evidence supporting the suggestion that cyclic manganate(V) diesters are intermediates in the reaction between alkenes and permanganate is compelling (47), and Simandi (48) has also suggested that a similar intermediate, 2, may occur during the oxidation of alkynes as in equation 4. 

It is a useful oxidant for hydrocarbons, alkenes, alcohols and aldehydes. Permanganate reacts with carbon-carbon double bonds to form a cyclic manganate(V) diester. The nature of the products is determined by subsequent rapid processes. 

Substitution of the VCP is tolerated both on and adjacent to the cyclopropane ring. Diester-substituted and heteroatom (O, NTs) tethers are well tolerated. Reactions were conducted with 2-10 mol% catalyst at up to 0.20 M, as illustrated. Most importantly, reactions with the naphthalene catalyst were found to be more rapid than those with other catalysts. For example substrate 54 is readily converted in >99% yield to cycloadduct 55 in only 15 min at room temperature (entry 1). Complex 93 efficiently catalyzes the reactions of both alkynes and alkenes with VCPs, offering greater generahty than thus far observed with non-rhodium catalysts. This catalyst is particularly advantageous in the cases of substrates 100 and 102, for which the desired product is not formed cleanly with Wilkinson s catalyst due to product isomerization. 

With this revision in our original plans, both alkenes and allenes were found to undergo efficient cycloadditions to produce cyclooctenone products in a new [6+2] cycloaddition process. This novel cycloaddition has been shown to proceed efficiently with alkenes tethered with sulfonamide, ether, or geminal diester Hnkers (Tab. 13.15, see page 294). Isomerization of the olefin, a potential competing reaction in this process, is not observed. Methyl substitution of either alkene in the substrate is well tolerated, resulting in the facile construction of quaternary centers. Of mechanistic importance, in some cases cycloheptene byproducts were isolated from [6+2] cycloaddition reactions in addition to the expected cyclooctenone products (that is, entries 3 and 4). 

Early work on the mechanisms of alkene cleavage by RuO has been briefly reviewed [50]. In the oxidation of 1,5-dienes to cA-tetrahydrofurandiols by RuO / aq. Na(10 )/EtOAc-acetone it is likely that there is cyclo-addition of RuO to one double bond of two 1,5-diene molecules to give a Ru(lV) diester this is oxidised by Na(lO ) to a Ru(Vl) diester, which is then hydrolysed to the organic product (Fig. 3.12) [345], and indeed Ru(Vl) diesters RuOlO R) have been isolated (Fig. 1.31) [323, 346]. ... 

Ru(0)(0jR)2 (R=7,8-didehydrocholesteryl acetate and cholesteryl acetate). These esters were isolated from RuO (as RuO /aq. Na(I04)/acetone) and R, and were shown by H and NMR and mass spectrometry to be Rn(VI) diesters similar to those obtained from the alkenes R with OsO. Their isolation, despite the absence of X-ray structural studies, suggests that such diesters could be involved in reactions of RuO, as indeed they are in the corresponding reactions with OsO. In each case a pair of isomeric diesters was formed (Fig. 1.31) [323, 346]. 

Both the reactions are essentially the additions of iodine carboxylate (formed in situ) to an alkene, i.e., the reaction of an alkene with iodine and silver salt. The Prevost procedure employs iodine and silver carboxylate under dry conditions. The initially formed transiodocarboxylate (b) from a cyclic iodonium ion (a) undergoes internal displacement to a common intermediate acylium ion (c). The formation of the diester (d) with retention of configuration provides an example of neighbouring group participation. The diester on subsequent hydrolysis gives a trans-glycol. 

Recently, the intramolecular nitrile oxide-alkene cycloaddition sequence was used to prepare spiro- w(isoxazolines), which are considered useful as chiral ligands for asymmetric synthesis (321). Reaction of the dibutenyl-dioxime (164) (derived from the diester 163) with sodium hypochlorite afforded a mixture of diastereomeric isoxazolines 165-167 in 74% combined yield (Scheme 6.80) (321). It was discovered that a catalytic amount of the Cu(II) complex 165-Cu(acac)2, where acac = acetylacetonate, significantly accelerated the reaction of diisopropylzinc... 

Keto esters are obtained by the carbonylation of alkadienes via insertion of the alkene into an acylpalladium intermediate. The five-membered ring keto ester 22 is formed from l,5-hexadiene[24], Carbonylation of l,5-COD in alcohols affords the mono- and diesters 23 and 24[25]. On the other hand, bicy-clo[3.3.1]-2-nonen-9-one (25) is formed in 40% yield in THF[26], l, 5-Diphenyl-3-oxopentane (26) and l,5-diphenylpent-l-en-3-one (27) are obtained by the carbonylation of styrene. A cationic Pd-diphosphine complex is used as the catalyst[27]. 

The cycloaddition of allenes to symmetrically disubstituted alkenes gives mixtures of cyclobutanes with stereochemical equilibration of the substituents. The reaction of 1,3-dimethylallenc with either diethyl fumarate or diethyl maleate produces a mixture of the /raw.v-bis(ethoxycar-bonyl)cyclobutanes.s The same nonstereoselectivity was observed for phenylallene and 1,1-dimelhylallene cycloadditions to maleic and fumaric acid diesters.9 10... 

Ketcnc equivalents, such as ketene acetals and thioacetals, can be used in cycloadditions to electron-deficient alkenes (see Sections 1.3.2.1. and 1.3.2.2.). In an example of a fumaric acid diester fitted with two chiral alcohol auxiliary groups, the aluminum(III)-catalyzed cycloaddition of 1,1-dimethoxyethene with di-(—)-menthyl fumarate (9) proceeds with > 99% diastereomeric excess. Intermediate 10 can be readily converted to cyclobutanone derivatives.17, 18... 

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