1,3-dipoles thiocarbonyl

As is the case with other 1,3-dipoles, thiocarbonyl ylides undergo [3 + 2]-cycloaddition reactions producing five-membered sulfur heterocycles [cf. (8)]. These ylides belong to the class of electron-rich 1,3-dipoles (89) and, according... 

In view of their very high reactivity with 1,3-dipoles, thiocarbonyl compounds were designated as superdipolarophiles [517]. Adducts were obtained with a large variety of dipoles and led to useful synthetic transformations. A few examples are given here (see [120] for references). 

Figure 8 Vectorially calculated dipole moments for the three planar conformations of l,l -thiocarbonyl-bis-...

Dithiolane isocyanate iminium methylides (55), are a new type of azomethine methylide derived 1,3-dipole, and undergo efficient and regioselective cycloaddition to thiocarbonyls to yield predominandy thiazolidine-2-thiones (56) <96TL711>. 

A destabilizing dipole-dipole interaction between the electron-deficient a-thiocarbonyl or a-carbonyl substituent and the double bond at R-[17],... 

Closely related to the already mentioned electrocyclizations of N-acyl thione S-imide (see Section 4.14.9.2) are some intermolecular cycloadditions involving this unusual class of 1,3-dipoles. Thus, the thione-S-imide intermediate (233) is probably involved in the formation of spirodithiazoline derivative (234) from the thione (235) and aryl azides <93HCA2147>. Also fluorenone-S-/ -tosylimide affords with carbonyl or thiocarbonyl compounds (R H) the corresponding oxathia- or dithia-zolidine derivatives (236) (Y = O or S) <80BCJ1023> (Scheme 44) (see also Section 4.14.6.1). 

Thiocarbonyl ylides (1) belong to tbe family of sulfur-centered 1,3-dipoles cbaracterized by tbe presence of two sp C atoms attached to tbe sulfur atom. Formal replacement of one of the C atoms by heteroatoms such as NR3, O, and S lead to the other representatives of the family, namely, thiocarbonyl S-imides (2), S-oxides (sulfines) (3), and S-sulfides (thiosulfines) (4), respectively. 

The dipolar structure 1 describes the chemical behavior of thiocarbonyl ylides best, although other mesomeric forms have been used for the representation of the electronic structure of these dipoles. The parent compound, thioformaldehyde (5)-methylide (1), was studied by means of spectroscopic and theoretical methods (2-5), which showed that the molecule possesses a bent allyl-type structure (6). According to theoretical calculations, structures lA and IB have the largest contribution (31.5% each) in the representation of the electronic structure, whereas 1C, which reflects the 1,3-dipolar character, has only a 4.2% contribution (5). 

In comparison with other 1,3-dipoles that have been extensively explored in organic synthesis (7), sulfur-centered 1,3-dipoles (1-4) are rather uncommon species. However, within the last two decades, remarkable progress has been made regarding both methods of generation and synthetic applications. In particular, thiocarbonyl ylides (1) were established as key intermediates useful for the preparation of sulfur-containing heterocyclic compounds. General methods for the preparation of thiocarbonyl ylides and their chemical reactivity have been reviewed (8-11). 

The desilylation methodology for the generation of 1,3-dipoles, developed by Vedejs and West (29) with regard to azomethine ylides, was successfully applied by Achiwa and co-workers (30) to the field of thiocarbonyl ylides. This approach allowed the generation of the parent thioformaldehyde (5)-methylide (la) and its use for preparative purposes (31,32). Generation of la in the presence of C=C dipolarophiles led to tetrahydrothiophenes (19) in high yield (Scheme 5.4). 

The reaction of the sterically crowded thiocarbonyl ylide 69 with highly electron-deficient alkenes such as 2,3-dicyano fumarate and maleate, tetracya-noethene, a-cyano cinnamates, and l,2-bis(trifluoromethyl)ethene-l,2-dicarboni-trile occurred in a nonstereospecific manner (27,89,96,97,136-138). The formation of a mixture of cis/trans tetrahydrothiophenes of type 82 is the result of a stepwise reaction involving zwitterionic intermediates of type 81 (Scheme 5.29). Ylide 69 fulfills the fundamental requirements for a two-step reaction with electron-deficient alkenes. This species corresponds to an electron-rich 1,3-dipole that also contains a bulky substituent at one terminus (89). 

The reaction of a thiocarbonyl and a-oxodiazo compound that leads to 1,3-oxathioles has been rationalized by a 1,5-dipolar electrocyclization reaction (178). It was suggested that an intermediate thiocarbonyl yhde bearing a C=0 function at the a-position (extended dipole) was first formed. Due to the low reactivity of a-oxodiazo compounds, these reactions were carried out at elevated temperatures or in the presence of rhodium acetate as the catalyst. In some cases, catalysis by LiC104 was also reported (77-80). 

Like many other 1,3-dipoles (e.g., nitrile ylides, imines, and oxides) (7), thiocarbonyl ylides undergo head-to-head dimerization to give sterically crowded 1,4-dithianes. The first reported example involves the formation of 2,2,3,3-tetraphenyl-l,4-dithiane (18) from thiobenzophenone (5)-methylide (16) (17,28) (cf. Scheme 5.3). Other (5)-methylides are known to form analogous 1,4-dithianes (e.g., thiofluorenone (5)-methylide yields 172) (17). The (5)-methylides of 4,4-dimethyl-2-phenyl-l,3-thiazole-5(4//)-thione (105) and methyl dithiobenzoate (60,104) dimerize to give compounds 173 and 174, respectively. 

In none of these experiments was the formation of the sterically more favored head-to-tail dimer observed. Though the mechanism of this dimerization is not completely understood, the regiochemistry observed may be related to the biradical character of the thiocarbonyl ylide dipole. 

When thiocarbonyl and ot-diazocarbonyl compounds are combined, acyl-substituted thiocarbonyl ylides 158 are generated from a nonisolable 3-acyl-1,2,4-thiadiazoline 157 (Scheme 8.36). In addition to giving acylthiiranes 159 and 1,3-dithiolanes 160, dipoles 158 can also 1,5-cyclize to produce 1,3-oxathioles 161. Acyl-thiocarbonyl ylides derived from diazoketones [e.g., HC(0)C(N2)R, R = Ph, f-Bu (219,220) 2-diazocyclohexanone (221)] produce 1,3-oxathioles [e.g., 162 (220), Scheme 8.36], while those derived from diazoesters (218,222,223) lead to thiiranes by 1,3-cyclization. Ylides derived from a-diazocarboxamides form 1,3-oxathioles (e.g., 163) and thiiranes (e.g., 159, R = f-Bu, R = NMePh, R = R" = Ph), depending on the nature of the substituents (220). A related 1,5-cyclization of an aminomethyl-thiocarbonyl ylide formed from dimethyl 3-anilino-2-diazobutanedioate was also reported (224). 

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