Cumulenes 5- -2-substituted

Treatment of geminal dihalocyclopropyl compounds with a strong base such as butyl lithium has been for several years the most versatile method for cumulenes. The dihalo compounds are easily obtained by addition of dihalocarbenes to double--bond systems If the dihalocyclopropanes are reacted at low temperatures with alkyllithium, a cyclopropane carbenoid is formed, which in general decomposes above -40 to -50°C to afford the cumulene. Although at present a number of alternative methods are available , the above-mentioned synthesis is the only suitable one for cyclic cumulenes [e.g. 1,2-cyclononadiene and 1,2,3-cyclodecatriene] and substituted non-cyclic cumulenes [e.g. (CH3)2C=C=C=C(CH3)2]. 

It will be convenient to consider under one heading all those unsaturated systems which do not fall under any of the sections previously discussed. There are four categories which are included in this catch-all heading. They are pyridones, quinones, multiple substitution at nonequivalent sites, allenes and cumulenes, and conjugated dienes and polyenes. 

There are absolutely no data sets for substituted allenes or cumulenes in the literature. This is a situation which should be remedied at the earliest opportunity, as data on these systems would be of considerable theoretical interest. 

Using standard references and protocol, we find the three reactions are respectively endothermic by ca 2, 8 and 6 kJmol-1, or ca 2, 4 and 3 kJmol-1 once one remembers to divide by 2 the last two numbers because the allene is dialkylated. So doing, from equations 10 and 11 we find an average ca 3 kJmol-1 (per alkyl group) lessened stability for alkylated allenes than the correspondingly alkylated alkenes. This is a small difference that fits most naturally in the study of substituted cumulenes such as ketenes and ketenimines, i.e. not in this chapter. But it is also a guideline for the understanding of polyenes with more cumulated double bonds. 

Starting with bromoallenes 133, nucleophilic substitution supported by the use of cuprous cyanide lead to cyanoallenes of type 134 (Scheme 7.22) [126, 131, 181]. Pro-pargyl precursors and also cumulenes of type 133 can be utilized for palladium-catalyzed aminocarbonylation to give allenic amides 135 (cf. Section 7.2.6) [182]. 

Synthetic applications of carbon radical additions to allenes cover aspects of polymerization, selective 1 1 adduct formation and homolytic substitutions. If heated in the presence of, e.g., di-tert-butyl peroxide (DTBP), homopolymerization of phenylal-lene is observed to provide products with an average molecular weight of 2000 (not shown) [58]. IR and 1H NMR spectroscopic analyses of such macromolecules point to the preferential carbon radical addition to CY and hence selective polymerization across the 2,3-double bond of the cumulene. Since one of the olefinic jr-bonds from the monomer is retained, the polymer consists of styrene-like subunits and may be... 

In principle, three basically different types of reaction modes are applied for cross-coupling reactions of allenes. First, cross-couplings of allenes with suitable halogen or metal substituents at one of the sp2-hybridized carbons furnish products still bearing the intact cumulene it-system. On this basis, numerous reactions for conversions of precursor 1 or 3 into substituted allenes 2 have been developed (Schemes 14.1 and 14.2). 

Second, substitution reactions of suitably a-functionalized allenes 4 result in compounds 5 which also still contain the unchanged cumulene system (Scheme 14.3). 

If allenes bear a potential leaving group in the a-position to the cumulene system, they are very attractive substrates for palladium-catalyzed substitutions. Examples are a-allenic acetates and particularly a-allenic phosphates, which react under palladium(O) catalysis with carbanions derived from /3-diesters, /i-keto esters, a-phenylsulfonyl esters and glycine ester derivatives. They lead to /3-functionalized allenes such as 86, 89 and 93 (Eqs. 14.9-14.11) [45 18]. 

Knoke and de Meijere [60] recently developed a highly flexible domino Heck-Diels-Alder reaction of a symmetrically substituted cumulene 125, which also involves cross-couplings of an allene at the central position. Both aryl and hetaryl halides react efficiently with l,3-dicyclopropyl-l,2-propadiene (125) and furnish 1,3,5-hexatriene derivatives 126 as intermediates, which are usually trapped by acceptor-substituted olefins in a subsequent cycloaddition, providing adducts 127a/b in moderate to good overall yields (Scheme 14.30). 

Addition of silyl radicals to cumulenes and their isoelectronic derivatives has mainly been studied by EPR spectroscopy. The adducts of MesSi radical with the two substituted allenes 54 and 55 have been recorded [73,74]. The attack occurs at the central atom affording unconjugated allyl-type radicals. In particular the adduct radical with 55 has been described as a very persistent perpendicular allyl radical [74]. 

Metal-catalyzed substitution reactions involving propargylic derivatives have not been studied in much detail until recently [311, 312]. In this context, the ability shown by transition-metal allenylidenes to undergo nucleophilic additions at the Cy atom of the cumulenic chain has allowed the development of efficient catalytic processes for the direct substitution of the hydroxyl group in propargylic alcohols [313]. These transformations represent an appealing alternative to the well-known and extensively investigated Nicholas reaction, in which stoichiometric amounts of [Co2(CO)g] are employed [314-317]. 

As already commented in the introduction of this chapter, regardless of its substitution pattern, the main trends of allenylidene reactivity are governed by the electron deficient character of the C and Cy carbon atoms of the cumulenic chain, the Cp being a nucleophilic center [9-15]. Thus, as occurs with their allcarbon substituted counterparts, electrophilic additions on 7i-donor-substituted allenylidene complexes are expected to take place selectively at Cp, while nucleophiles can add to both C and Cy atoms. However, the extensive 71-conjugation present in these molecules results in a reduced reactivity of the cumulenic chain and, in some cases, in marked differences in the regioselectivity of the nucleophilic additions when compared to the all-carbon substituted allenylidenes. In the following subsections updated reactivity studies on 7i-donor-substituted allenylidene complexes are presented by Periodic Group. 

For 64-70 reversible potentials RED 7SEM can be obtained at -55 °C only in DMF from which protic impurities have been removed One should keep in mind that here the levels RED (and SEM) exist as heterocyclic substituted cumulenes which may rapidly polymerize. 

Analogous -substitutions take place when cumulenic ethers anti Grignard compounds are allowed. to interact in the presence of catalytic quantities of cqpper(I) salts. Organocopper compounds are the presumed intermediates [163,164]. 

There are many reactions in which pyridines are used as bases. However in a large number of reactions only pyridine itself is reactive. a-Substituted pyridines behave differently, e.g. in the catalysis of acylation reactions with acyl chlorides or anhydrides [45]. The sterical hinderance of the a-substituents decelerates reactions in which a pyridine reacts as a nucleophile. A reaction which can be base-catalyzed by a-substituted pyridines is the addition of alcohols to hetero-cumulenes such as ketenes and isocyanates. Therefore this reaction was investigated as a model reaction for base catalysis by concave pyridines. 

Cyclodimerization of unsymmetrically substituted butatricncs such as 12 give both head-to-head and hcad-to-tail cycloaddition products. The structure of the head-to-head dimer was confirmed by its independent synthesis from the mixed cycloaddition of cumulenes 8 and 10,21 22 These dimerizations proceed by discrete nickel cyclopentanes which was established by the isolation of the 2-bispyridinenickel complex of the l.l,4,4-tetramelhylbuta-l,2,3-triene dimer.23 4-Radialenes with extended conjugation, potential organic conductors and semiconductors, have been prepared by similar methods as illustrated by the examples below.24,25... 

The first nonintroductory section of the text starts with the observation made early in this century that cyclopropanes have significant olefinic character. That is, corresponding ethylene and cyclopropane derivatives have significant similarities. There are literature comparisons of the thermochemistry of direct counterparts such as the parent species (1 and 2, X = H), propene and methylcyclopropane with X = Me, and of methyl acrylate and methyl cyclopropanecarboxylate 8 with X = COOMe. But the chemistry of substituted eth-ylenes is far richer than just that of vinyl compounds. One can retrieve enthalpy of formation data for cumulenes ( cumulenated olefins) such as allene (3) and both cis- and trans-2,3,4-hexatriene (4a and 4b), and for conjugated olefins such as 1,3-butadiene (5) and both (Z)- and (E)-1,3,5-hexatriene (6a and 6b). For the cyclopropane chemist it is natural to... 

Ethanolysis of the a-ethynyl-substituted vinyl triflates 93-95 proceeds via the intermediacy of the cumulenic dicoordinated cations 96-98 (equation 17) and suggests the following stability order for the carbocations 98 > 96 > 9745. The same relative reactivity order was found for the triflates 99-10145. 

A method used to prepare four of six possible thienopyridines (1992S528, 1997S949, 1998S1095) holds considerable promise. In particular, the synthesis of thieno[2,3-6]pyridine derivatives 31 and 32 involves the reaction of 2-chloro-3-(cyanomethyl)pyridine (33) and ethyl 2-chloro-3-pyridylacetate (34) with hetero-cumulenes, such as carbon disulfide and phenyl isothiocyanate. The reaction proceeds through the formation of the corresponding dianions 35 and 36 followed by cyclization through intramolecular nucleophilic substitution of the chlorine atom. 

The dimerization of the diphosphallene has an interesting parallel with the carbodiphosphoranes. The chloro-substituted A5 phospha-cumulene reacts under cycloaddition to give the diphosphacyclobuta-diene dichloride [Eq. (56)] (120a, 120b). 

---