Alkenes production from furans

The Pd—C cr-bond can be prepared from simple, unoxidized alkenes and aromatic compounds by the reaction of Pd(II) compounds. The following are typical examples. The first step of the reaction of a simple alkene with Pd(ll) and a nucleophile X or Y to form 19 is called palladation. Depending on the nucleophile, it is called oxypalladation, aminopalladation, carbopalladation, etc. The subsequent elimination of b-hydrogen produces the nucleophilic substitution product 20. The displacement of Pd with another nucleophile (X) affords the nucleophilic addition product 21 (see Chapter 3, Section 2). As an example, the oxypalladation of 4-pentenol with PdXi to afford furan 22 or 23 is shown. 

Hydroxy-THISs react with electron-deficient alkynes to give nonisol-able adducts that extrude carbonyl sulfide, affording pyrroles (23). Compound 16 (X = 0) seems particularly reactive (Scheme 16) (25). The cycloaddition to benzyne yields isoindoles in low- yield. Further cyclo-addition between isoindole and benzyne leads to an iminoanthracene as the main product (Scheme 17). The cycloadducts derived from electron-deficient alkenes are stable (23, 25) unless highly strained. Thus the two adducts, 18a (R = H, R = COOMe) and 18b (R = COOMe, R = H), formed from 7, both extrude furan and COS under the reaction conditions producing the pyrroles (19. R = H or COOMe) (Scheme 18). Similarly, the cycloadduct formed between 16 (X = 0) and dimethylfumarate... 

Cyclotrithiazyl chloride is also a useful reagent in organic chemistry in the fusion of 1,2,5-thiadiazoles to quinones as well as the synthesis of (a) isothiazoles from 2,5-disubstituted furans and (b) bis-1,2,5-thiadiazoles from A-alkylpyrroles (Scheme 8.4). Alkenes and alkynes react readily with (NSC1)3 to give 1,2,5-thiadiazoles, while 1,4-diphenyl-1,3-butadiene gives a variety of heterocyclic products including a bis(l, 2,5-thiadiazole). ... 

Diterpenoids related to lambertianic acid were prepared by intramolecular cyclization of either an alkene or an alkyne with a furan ring <2005RJ01145>. On heating amine 101 with allyl bromide, the intermediate ammonium ion 102 was formed which then underwent [4+2] cycloadditions in situ to give the spiroazonium bromides 103 and 104 (Scheme 13). These isomers arose from either endo- or co-transition states. The analogous reaction was also carried out with the same amine 101 and propargyl bromide. The products 105 and 106 contain an additional double bond and were isolated in 58% yield. The product ratios of 103 104 and 105 106 were not presented. 

A survey of Wacker-type etherification reactions reveals many reports on the formation of five- and six-membered oxacycles using various internal oxygen nucleophiles. For example, phenols401,402 and aliphatic alcohols401,403-406 have been shown to be competent nucleophiles in Pd-catalyzed 6- TZ /fl-cyclization reactions that afford chromenes (Equation (109)) and dihydropyranones (Equation (110)). Also effective is the carbonyl oxygen or enol of a 1,3-diketone (Equation (111)).407 In this case, the initially formed exo-alkene is isomerized to a furan product. A similar 5-m -cyclization has been reported using an Ru(n) catalyst derived in situ from the oxidative addition of Ru3(CO)i2... 

Attempts to liberate l-methyl-l-aza-2,3-cyclohexadiene (329) from 3-bromo-l-methyl-l,2,5,6-tetrahydropyridine (326) by KOtBu in the presence of [18]crown-6 and furan or styrene did not lead to products that could have been ascribed to the intermediacy of 329 (Scheme 6.70) [156], Even if there is no doubt as to the allene nature of 329 on the basis of the calculations on the isopyridine 179 and 3d2-lH-quinoline (257), it is conceivable that the zwitterion 329-Za is only a few kcal mol-1 less stable than 329. This relationship could foster the reactivity of 329 towards the tert-butoxide ion to an extent that cycloadditions to activated alkenes would be too slow to compete. On the other hand, the ultimate product of the trapping of 329 by KOtBu could have been an N,0-acetal or a vinylogous N,0-acetal, which might not have survived the workup (see, for example, the sensitivity of the N,0-acetal 262 [14], Scheme 6.57). 

It is remarkable that furan and 2,3-dimethyl-l,3-butadiene were used to trap 351 when it was generated from 354 as well as 376. In both cases, the same products resulted and even the 365 366 ratios were closely similar in view of the different reaction conditions. This is convincing evidence for 351 existing as a separate species, unassociated with LiF or KBr, the second products of the eliminations from the progenitors en route to 351. The first successful use of unactivated alkenes [( )- and... 

It is interesting to note that head-to-tail dimeric structures are proposed for these products. On the other hand, the head-to-head cyclobutane dimers 15 and 16 are obtained on isomerization of the propellanes 13 and 14. respectively.8 The bridgehead alkenes have been proposed as intermediates as is evident from trapping of the adducts with furan. An X-ray crystallographic study of 15 confirmed the configurations of both cyclobutanes 15 and 16 indicating syn head-to-head dimerization, as 15 could cleanly be converted to 16 by catalytic hydrogenation. 

Further cycloaddition reactions of silylenes generated by the photolysis of cyclotrisilanes have been published since Weidenbruch and coworkers summarized these reactions in an excellent review. Different siliranes were prepared by [2+1]-cycloaddition of di-t-butylsilylene to various alkenes and dienes (Scheme 6)46. Quite interesting results are obtained from the photolysis of hexa-i-butylcyclotrisilane in the presence of unsaturated five-membered ring compounds47 (Scheme 7). With cyclopentadiene and furane, [4 + 2]-cycloaddition of the photolytically generated disilene occurs only as a side reaction. Furthermore, [2 + 1]-cycloaddition of the intermediately formed silylene is highly favored and siliranes are primarily obtained. A totally different course is observed for the reaction in the presence of thiophene. The disilene abstracts the sulfur atom with the formation of the 1,2-disilathiirane as the major product with an extremely short Si—Si distance of 230.49 pm. 

Based on these results and the disadvantageously high volatility of hexane, Huber et al. decided to develop another approach utilizing 5-hydroxymethylfurfural (5-HMF) or furfural, compounds that can be obtained from the dehydration of glucose or xylose, respectively [54-57]. The production of Cg-Ci5 alkenes from these furans is achievable by sequential aldol condensation with acetone followed by hydrogenation... 

The consecutive alkenyl mechanism (Figure 3) was put forward as the route for oxidation of unsaturated reactants. The weakly adsorbed intermediates are presumed to be in equilibrium with the gas phase, which enables furan to be seen as a product in butene oxidation (22,24,27). In contrast to the previous work, this study included an examination of the fact that none of the alkene intermediates desorb from the catalyst. It was proposed that the reaction proceeded via more strongly adsorbed alkoxide intermediates that would remain on the surface for the whole oxidation sequence (Figure 5). 

Dichlorotricyclo[4.2.1.0 ]non-3-ene (20) is even more strained and rearranges on warming to room temperature. The main products were derived from reactions of the unstable bridgehead alkene, 6,9-dichlorobicyclo[4.2.1]nona-l(9),3-diene (21), which was formed as a transient intermediate. This species dimerized to give 22, or could be trapped as a cycloadduct 23 with furan. ... 

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