Heterocumulenes heterocyclics

Table 2 illustrates 1,3-dipoles with a double bond and with internal octet stabilization, commonly referred to as the propargyl-allenyl anion type. These are all reactive dipoles and a large number of five-membered heterocycles can be constructed from these readily available dipoles, especially when the dipolarophile is varied to include heterocumulenes, etc. 

Anions of heterocyclics may attack heterocumulenes to set up systems which can incorporate new atom sequences into the ring by nucleophilic attack on a ring site (such as a carbonyl group). Scheme 32 gives an example (80AG(E)466). 

Four-membered heterocycles are easily formed via [2-I-2] cycloaddition reac tions [65] These cycloaddmon reactions normally represent multistep processes with dipolar or biradical intermediates The fact that heterocumulenes, like isocyanates, react with electron-deficient C=X systems is well-known [116] Via this route, (1 lactones are formed on addition of ketene derivatives to hexafluoroacetone [117, 118] The presence of a trifluoromethyl group adjacent to the C=N bond in quinoxalines, 1,4-benzoxazin-2-ones, l,2,4-triazm-5-ones, and l,2,4-tnazin-3,5-diones accelerates [2-I-2] photocycloaddition processes with ketenes and allenes [106] to yield the corresponding azetidine derivatives Starting from olefins, fluonnaied oxetanes are formed thermally and photochemically [119, 120] The reaction of 5//-l,2-azaphospholes with fluonnated ketones leads to [2-i-2j cycloadducts [121] (equation 27)... 

Helical structurespolysilane, 139-141, 163 Heterocumulenes, 25-29 Heterocycles, 251, 252, 275, 276 organoantimony, 104-105, 116-118 R2MER/,X type, 257-275 as single source precursors, 299-303... 

Due to their high electrophihcity, isocyanates are useful starting materials for the synthesis of heterocycles and C-C bond formation using carbon nucleophiles. A key feature of these reactions is the requirement for more than one equivalent of base. Additionally, a few examples of transition metal-catalyzed homologation of the central carbon of the heterocumulene moiety have been reported. 

Forty-four five-membered heterocycles of type A (13, 19) have been described (Table I). If the atoms or groups a, b, c, d, e, and f are selected from suitably substituted carbon, nitrogen, oxygen, and sulfur atoms, then with these conditions it can be shown that 144 structural possibilities are provided by the general formula 19. The number of structural possibilities can be deduced in various ways, but a very useful approach is to regard type A meso-ionic molecules (19) as being derived by the union (-<—u— ) of 1,3-dipoles (34) and heterocumulenes (35). 

A full account of the preparation and 1,3-dipolar cycloaddition reactions of this class of meso-ionic heterocycle (105) has now been published. Using olefinic dipolarophiles or heterocumulenes, a number... 

The 1,3-dipolar cycloaddition of a-keto carbenoids to the polar double bond of heterocumulenes provides a direct access to five-membered heterocycles. The reaction of a-diazo ketones 132 with phenyl isocyanate in the presence of a Rh2(OAc)4 catalyst affords the 1,3-cycloadduct, 3-phenyl-2(3//)-oxazolones 133 (Fig. 5.32). ... 

Synthesis of Heterocycles Using Heterocumulenes Conjugated With Carbonyl Groups O. Tsuge, Kagaku no Ryoiki, Zokan, 1980, 35-69. 

Heterochalcogenides, with chromium, 5, 312 Heterocoupling reactions in olefin cross-metathesis, 11, 181 Pd-catalyzed, alkynes, 8, 274—275 Heterocubanes, reactions, 3, 8 Heterocumulenes in insertion reactions, 1, 107 nickel metallacycle reactions, 8, 103-104 Heterocyclic compounds... 

Reaction kinetics for the interaction of 5-alkyliminothiatriazoles 52 or 58 with heterocumulenes, nitriles, ketones, imines, or other dipolarophiles a=b show that the decomposition of the thiatriazole is bimolecular, and new heterocyclic five-membered rings 71 are formed (Scheme 15). The term masked 1,3-dipolar cycloaddition was used by L abbe and co-workers for this type of reaction <1978JOC4951>, the thioimidate function being the masked 1,3-dipole. The reaction is thought to involve a thiapentalenic intermediate 70 with hypervalent sulfur. The product 71 is itself a masked dipole and often further reactions take place. 

Cycloaddition reactions of transient or isolable disilenes with heterocumulenes such as CX2 (X = S, Se) produce heterocyclic carbenes, for example, carbene 59, which has a disilane backbone. These carbenes are only transient species and were not isolated but were either trapped with C6o. or dimerization of the carbenes occurred to give the tetrathiafulvalene or tetraselenafulvalene analogues 28 <2002CEJ2730, 2005AGE7567>. 

However, the most important goal that might be reached by the application of coordination catalysts for the polymerisation of heterounsaturated monomers is the possibility of the enchainment of heterounsaturated monomers, not susceptible to homopropagation, via their copolymerisation with heterocyclic monomers. This concerns primarily the coordination copolymerisation of carbon dioxide and oxacyclic monomers such as epoxides, leading to aliphatic polycarbonates [8 12]. Representative examples of the copolymerisations of heterocyclic monomers and hardly homopolymerisable heterocumulenes, in the presence of coordination catalysts, are listed in Table 9.4 [1]. 

Table 9.4 Copolymerisation of heterocyclic monomers with heterocumulenes in the presence of coordination catalysts 2...

Semiempirical calculations have been applied to antiaromatic three-membered rings and indicate that they correspond to energy minima <1973CC688>. For example, thiirene 13 corresponds to a local energy minimum relative to the isomeric carbene 14, zwitterion 15, heterocumulene 16, and heterocyclic carbene 17. 

Nina A. Nedolya was born in Irkutsk (Russia) and educated in organic chemistry at the Irkutsk State University (Diploma 1972, PhD 1982, DSc 1998). From 1995 to 1999 she was associated with Prof. L. Brandsma at the Utrecht University (The Netherlands). In 1999 she obtained her second PhD from the Utrecht University. She is presently Head of the Research Group of Chemistry of Heterocyclic Compounds at A. E. Favorsky Irkutsk Institute of Chemistry. She is the author of over 210 review articles and research papers. She is also one of the inventors for 112 patents. She is interested in the chemistry of polyfunctional unsaturated heteroatomic systems (vinyl, allenyl, and alkynyl ethers and their derivatives, linear and cyclic heteropolyenes, hetero-cumulenes), including synthesis of important heterocycles, particularly pyrroles, thiophenes, thiazoles, imidazoles, dihydrofurans, dihydropyridines, pyridines, quinolines, dihydroazepines, and azepines, based on metallated allenes or alkynes and/or heterocumulenes. 

Carbodiimides also play a role as building blocks of numerous N-heterocycles. Examples are the cycloaddition reactions of carbodiimides. In the formation of [2-1-2] cycloadducts N-methyl-N -t-butylcarbodiimide is used as a marker to determine the mode of addition of isocyanates or isothiocyanates to carbodiimides. In these reactions addition across the C=N or the C=0 bond of the isocyanate or across the C=N or the C==S bond of the isothiocyanate can occur. Addition to the N-methyl-N -t-butylcarbodiimide always proceeds across the N-methyl double bond. Also, theretroreaction of the [2-1-2] cycloaddition reaction of carbodiimides can afford a different set of heterocumulenes. ... 

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