Thioketene

Ketenes and related compounds have been reviewed extensively (1 9). For the synthesis and synthetic uses of conjugated ketenes see Reference 10. Ketenes with three or more cumulated double bonds have been prepared (11,12). The best known is carbon suboxide [504-64-3] 3 2 preparative uses and has been reviewed (13—16). Thioketenes (17,18), ketenimines (19—21), and their dimers show interesting reactivity, but they have not achieved iadustrial importance to date. 

Physical Properties. Ketenes range ia their properties from colorless gases such as keteae and methylketene [6004-44-0] to deep colored hquids such as diphenylketene [525-06-4] and carbon subsulftde [627-34-9]. Table 1 lists the physical state mp, and bp for certain ketenes, thioketenes, and ketenimines. 

Table 1. Properties of Some Ketenes, Thioketenes, and Ketenimines...

StericaHy hindered or very electrophilic substituted ketenes, such as diphenylketene, di-Z rZ-butylketene [19824-34-17, and bis(trifluoromethyl)ketene, are quite stable as monomers. Ketenimines tend to polymerize. The dimerization of thioketenes results in 1,3-dithiacyclobutanones (6) (45), a type of dimer not observed with ketenes. 

Thioketenes can be prepared in several ways, from carboxyHc acid chlorides by thionation with phosphoms pentasulfide [1314-80-3] 2 5 ketene dithioacetals by -elimination, from l,2,3-thiadia2oles with flash pyrolysis, and from alkynyl sulfides (thioacetylenes). The dimeri2ation of thioketenes to 2,4-bis(alkyHdene)-l,3-dithietane compounds occurs quickly. They can be cleaved back pyrolyticaHy (63). For a review see Reference 18. 

Physical Properties. Dimeric ketenes are colorless to dark brown Hquids or crystalline soHds with a broad range of melting and boiling points. Table 2 Hsts examples of dimeric ketenes and thioketenes. 

Isothiazole behaves as a typical stable aromatic molecule. Thermolysis of substituted isothiazoles at 590 °C leads to the formation of thioketenes (80MI41700) and phenyl-isothiazoles undergo photoisomerism (Section 4.17.6.2) (73BSF1743, 81T3627). 1,2-Benzisothiazole boils at 220 °C without appreciable decomposition, and the 2,1-isomer... 

Thiirenes are photochemically converted to thioketenes or to alkynylthiols (Scheme 22) (80PAC1623). 2-Acetyl-3-methylthiirene rearranges on irradiation at 310 nm to a mixture of acetylmethylthioketene and thioacetylmethylketene, identified by their IR spectra (80NJC703). 2,3-Diphenylthiirene 1-oxide at 130 °C is believed to be isomerized to monothiobenzil which is air-oxidized to benzil (Scheme 23) (79JA390). 

Thiirenes have been isolated in argon matrices at 8 K by photolysis of 1,2,3-thiadiazoles or vinylene trithiocarbonates (Scheme 151) (80PAC1623, 8UA486). They are highly reactive and decompose to thioketenes and alkynes (Scheme 22). Electron withdrawing substituents stabilize thiirenes somewhat, but no known thiirene is stable at room temperature unlike the relatively stable thiirene 1-oxides and thiirene 1,1-dioxides. 

From 0-lactam-4-sulfenic acids Thioketene + isocyanate... 

In an interesting contrast to the photochemical behavior of the simpler sulfine system, the photolysis of thioketene S-oxides such as 25 in carbon tetrachloride leads to the corresponding thioketenes in excellent yield36. This photochemical deoxygenation is... 

Thio-Claisen rearrangement 746-748 Thioketene 5-oxides photolysis of 878 reactions of 277 Thiolane dioxides formula of 382 NMR spectra of 460 reactions of 604 synthesis of 461 Thiolane oxides 747 formula of 382 IR spectra of 461 synthesis of 461, 462, 752 Thiolanes, photolysis of 881 Thiolene dioxides formula of 382 NMR spectra of 460 reactions of 464, 465 synthesis of 461 Thiolene oxides formula of 382 synthesis of 461, 746 Thiols... 

Vallee Y., Ripoll J. L. Synthesis of Thioaldehydes, Thioketones and Thioketenes... 

The enolates of other carbonyl compounds can be used in mixed aldol reactions. Extensive use has been made of the enolates of esters, thiol esters, amides, and imides, including several that serve as chiral auxiliaries. The methods for formation of these enolates are similar to those for ketones. Lithium, boron, titanium, and tin derivatives have all been widely used. The silyl ethers of ester enolates, which are called silyl ketene acetals, show reactivity that is analogous to silyl enol ethers and are covalent equivalents of ester enolates. The silyl thioketene acetal derivatives of thiol esters are also useful. The reactions of these enolate equivalents are discussed in Section 2.1.4. 

This reaction occurs through a TS in which the aldehyde is chelated, but the silyl thioketene acetal is not coordinated to the Ti (open TS). 

Entries 3 and 8 show additions of a silyl thioketene acetal to a-substituted... 

E- and Z-silyl thioketene acetals give the 2,3-anti product. The 3,4-syn ratio is 50 1, and is consistent with the Felkin model. When this nucleophile reacts with 2-benzyloxypropanal (Entry 8), a chelation product results. The facial selectivity with respect to the methyl group is now reversed. Both isomers of the silyl thioketene acetal give mainly the 2,3-syn-3A-syn product. The ratio is higher than 30 1 for the Z-enolate but only 3 1 for the F-enolate. 

The (3-methoxy group in Entry 12 has a similar effect. The aldehydes in Entries 13 and 14 also have a-methyl-(3-oxy substitution and the reactions in these cases are with a silyl ketene acetal and silyl thioketene acetal, respectively, resulting in a 3,4-syn relationship between the newly formed hydroxyl and a-methyl substituents. 

This and similar catalysts are effective with silyl ketene acetals and silyl thioketene acetals.155 One of the examples is the tridentate pyridine-BOX-type catalyst 18. The reactivity of this catalyst has been explored using a- and (3-oxy substituted aldehydes.154 a-Benzyloxyacetaldehyde was highly enantioselective and the a-trimethylsilyoxy derivative was weakly so (56% e.e.). Nonchelating aldehydes such as benzaldehyde and 3-phenylpropanal gave racemic product. 3-Benzyloxypropanal also gave racemic product, indicating that the (i-oxy aldehydes do not chelate with this catalyst. 

Several catalysts based on Ti(IV) and BINOL have shown excellent enantiose-lectivity in Mukaiyama aldol reactions.156 A catalyst prepared from a 1 1 mixture of BINOL and Ti(0-i-Pr)4 gives good results with silyl thioketene acetals in ether, but is very solvent sensitive.157... 

The enantioselectivity of Sn(II) enolate reactions can be controlled by chiral diamine additives. These reagents are particularly effective for silyl thioketene acetals.162 Several diamines derived from proline have been explored and l-methyl-2-(l-piperidinomethyl)pyrrolidine 21 is an example. Even higher enantioselectivity can be achieved by attachment of bicyclic amines to the pyrrolidinomethyl group.163... 

Silyl acetals of thiol esters have also been studied. With TiCl4 as the Lewis acid, there is correspondence between the configuration of the silyl thioketene acetal and the adduct stereochemistry.314 L-Isomers show high anti selectivity, whereas Z-isomers are less selective. 

A number of other chiral catalysts can promote enantioselective conjugate additions of silyl enol ethers, silyl ketene acetals, and related compounds. For example, an oxazaborolidinone derived from allothreonine achieves high enantioselectivity in additions of silyl thioketene acetals.323 The optimal conditions for this reaction also include a hindered phenol and an ether additive. 

Thioketenes (83) are generally unstable and very reactive, although bis (trifluoromethyl)thioketene (83 R1 = CF3) is stable enough for isolation. 

Raasch, and Schaumann and co-workers, have studied the reactions of bis (trifluoromethyl)thioketene (83 R1 = CF3) with alkenes, with thioketones, and with carbodiimides or Schiff-base imines. The products were, respectively, thietans, 1,3-dithietans (84 R1 = CF3), and 1,3-thiazetidines (85 R1 = CF3) (from the carbodiimide).114,115 With phenyl azide the 1,2,3,4-thiatriazoline (86 R = CF3) is formed subsequent pyrolysis yields2,l-benzisothiazole.114... 

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