Sulfur-extrusion

Diallylsulfonium salts undergo intramolecular allylic rearrangement with strong bases to yield 1,5-dienes after reductive desulfurization. The straight-chain 1,5-dienes may be obtained by double sulfur extrusion with concomitant allylic rearrangements from diallyl disulfides. The first step is achieved with phosphines or phosphites, the second with benzyne. This procedure is especially suitable for the synthesis of acid sensitive olefins and has been used in oligoisoprene synthesis (G.M. Blackburn, 1969). 

Ring contraction of heterocycles by sulfur extrusion 96AHC(65)39. 

Dipolar eycloaddition reaction of thioisomiinchnones 208 with dimethyl aeetylenediearboxylate (DMAD) furnished adduets 209, whieh underwent a sulfur extrusion to give 2-substituted-7-phenyl-l,8-dioxo-l//,8//-pyrido[l,2-c]pyrimidine-5,6-dicarboxylates 210 (OOOL581). 

Sulfur extrusion is the main decomposition pathway, with 1-benzothiepins being more stable than 3-benzothiepins. The required 6it disrotatory electrocyclic process leads to a loss of aromaticity for the [6]annulated benzene ring, whereas the [r/]benzene derivative 4 leads to a thianorcaradiene derivative with less disturbed aromaticity of the benzene ring. 

Thus, sulfur extrusion from the twisted naphtho[3,4-c/]thiepin is rapid, because in this case less energy is required to form the thianorcaradiene isomer than for a total loss of aromaticity. 

Thermodynamic parameters have been obtained from kinetic HNMR spectroscopic studies of the thermal decomposition of ethyl 2,7-di-to7-butyl-5-methylthiepin-4-carboxylaten and two 1-benzothiepin compounds.12 The activation parameters for sulfur extrusion are AH = 93.7 kJ mol - 1 and AS = — 112.6 J Kmol-1 (in [2H18]Decalin) for the thiepin derivative,11 and AH = 75.3 and 87.9 kJ mol1 and AS = —100.4 and —104.6J Kmol-1 (in [2Hs]toluene) for the benzothiepin compounds.12 The large negative activation entropy values are consistent with a high degree of order in the anticipated thianorcaradiene transition state of the sulfur extrusion reaction. 

In some sulfur extrusions from 2,7-di-/ Tt-butylthiepins a byproduct containing two sulfur atoms is obtained, along with the aromatic compound. The byproduct has been characterized as a thienothiophene by single crystal X-ray analysis.92... 

Also, the different stabilities of 3-benzothiepins are reflected by the conditions of sulfur extrusion dibenzo[A,d]thiepin (13) is desulfurized by triphenylphosphane in refluxing xylene, while ethyl 3-benzothiepin-2-carboxylate (14) (see Section 2.1.3.4.) already loses sulfur at room temperature with a half-life of 54 minutes.5... 

Thiophenes are less reactive than furans and therefore react with very reactive dienophiles. They behave somewhat differently from furans and in many cases the intermediate addition products are unstable and undergo cheleotropic extrusion of sulfur [30]. Thiophenes 30 undergo cycloaddition reactions with DMAD (Equation 2.11) to afford bicyclic cycloadducts which lead to phthal-ates by sulfur extrusion, thus offering a one-pot synthesis of dimethylphthalates [31]. 

In connection with the chemistry of the reactive transient species, nitrene, the chemistry of azepines is well documented u. Also, the chemistry of oxepins has been widely developed due to the recent interest in the valence isomerization between benzene oxide and oxepin and in the metabolism of aromatic hydrocarbons 2). In sharp contrast to these two heteropins, the chemistry of thiepins still remains an unexplored field because of the pronounced thermal instability of the thiepin ring due to ready sulfur extrusion. Although several thiepin derivatives annelated with aromatic ring(s) have been synthesized, the parent thiepin has never been characterized even as a transient species3). 

At present, the problems in thiepin chemistry awaiting solution are (i) how to construct the thiepin skeleton under mild reaction conditions, (ii) what are the structural effects on thermal stability of thiepin, (iii) whether the thianorcaradiene is an intermediate of sulfur extrusion reaction or not, (iv) what is the molecular structure of the thiepin (planar or nonplanar), (v) what is the antiaromaticity of the thiepin ring. 

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