Selenium selenoxides

This ch ter contains reactions which prepare the oxides of nitrogen, sulfur and selenium. Included are W-oxides, nitroso and nitro compounds, nitrile oxides, sulfoxides, selenoxides and sulfones. Oximes are considered to be amines and appear in those sections. Preparation of sulfonic acid derivatives are found in Chapter Two and the preparation of sulfonates in Chapter Ten. 

This reaction depends upon the facile solvolysis of (J-haloselenides and the facile oxidative elimination of a selenoxide, which was discussed in Section 6.6.3. An alternative method, which is experimentally simpler, involves reaction of alkenes with a mixture of diphenyl diselenide and phenylseleninic acid.189 The two selenium reagents generate an electrophilic selenium species, phenylselenenic acid, PhSeOH. 

In another elegant approach (Scheme 18), a synthesis of 5-alkenyl-substituted 1,2,4-oxadiazoles relies upon a selenoxide. -elimination at the 5-a-carbon of the selenium resin-supported 1,2,4-oxadiazole 152. Access to compound 152 was achieved in two steps from the supported oxadiazole 150, which underwent deprotonation and alkylation at the 5-a-carbon to give the a-alkylated selenium resin 151. 1,3-Dipolar cycloaddition then gave the selenium resin-supported 1,2,4-oxadiazole 152 <2005JC0726>. 

The conversion of the polystyrene-supported selenyl bromide 289 into the corresponding acid 290 allowed dicyclohexylcarbodiimide (DCC)-mediated coupling with an amidoxime to give the 1,2,4-oxadiazolyl-substituted selenium resin 291 (Scheme 48). Reaction with lithium diisopropylamide (LDA) and allylation gave the a-sub-stituted selenium resin 292, which was then used as an alkene substrate for 1,3-dipolar cycloaddition with nitrile oxides. Cleavage of heterocycles 293 from the resin was executed in an elegant manner via selenoxide syn-elimination from the resin <2005JC0726>. 

The most versatile approach to disulfonium dications - reaction of triflic anhydride with monosulfoxides of bis-sulfides - has certain limitations in the case of selenium. Most importantly, selenoxides that contain (3-hydrogen atoms are labile.120 122 Trimethylsilyl triflate was used instead of triflic anhydride for synthesis of dication 112 from a selenoxide 111 (Scheme 43).123... 

The lesser electrophilicity of the selenium and tellurium derivatives is also displayed in their hydrolytic stability. In general, all diselenonium dications are more stable toward hydrolysis than the corresponding disulfonium dications. 1,5-Diselenoniabicyclo[3.3.0]octane 113, which is expected to be hydrolyzed to an unstable selenoxide, is stable in water.124 On the other hand, dication 112 is... 

Optically active selenoxides are known to be unstable toward racemization. An optically active selenoxide having a steroidal frame was obtained for the first time by Jones and co-workers in 1970.7 Enantiomeric selenoxides were prepared by Davis et al. in 1983,8 and an enantiomerically pure selenoxide was isolated for the first time by us in 1989.9 Many optically active selenoxides, which are kinetically stabilized by bulky substituents, were synthesized over the last two decades, and their stereochemistry and stability toward racemization were studied.3,5,10 Recently, some optically active selenoxides, which were thermodynamically stabilized by the intramolecular coordination of a Lewis base to the selenium atom, have been isolated. Optically active selenoxides 1 and 2 were obtained by optical resolution on chiral columns, and their stereochemistry and stability toward racemization under various conditions were clarified (Scheme 1).11,12... 

Not only propargyl precursors but also acceptor-substituted 1-methyleneallyl compounds such as 67, 71 or 74 can be used to produce the target allenes by sigmatropic reactions (Scheme 7.10). After oxidation of selenium compounds 67 followed by equilibration of the resulting selenoxides 68 and selenenic esters 69, hydrolysis... 

Selenoxides and telluroxides also function as mild oxidants for the conversion of thiols to disulfides as shown in equations (16) and (17) for the reaction of thiophenol with diphenylselenoxide (47) and diphenyltelluroxide (48). Mechanistically, the oxidation of thiols to disulfides with selenoxides and telluroxides is a multi-step process, which takes advantage of the ease with which tellurium(IV) and selenium(IV) species form trigonal bipryamidal... 

Samarium(II) iodide, 46, 3 Sandmeyer reaction, 2, 7 Schiemann reaction, 5, 4 Schmidt reaction, 3, 8, 9 Selenium dioxide oxidation, 5, 8 24, 4 Seleno-Pummerer reaction, 40, 3 Selenoxide elimination, 44, 1 Shapiro reaction, 23, 3 39, 1 Silanes ... 

It is interesting to discern the different migratory aptitudes displayed by spirocyclic ketones on exposure to hydrogen peroxide [252] (Eq. 226,227). Although participation of the selenium atom to direct the attack of the peroxide has been formulated, the results are also consistent with an electronic explanation. Thus, the rapid formation of selenoxide renders the spirocyclic center acceptor-like through polarity alternation, and the migration of the methylene group becomes more favorable. 

Resin-bound selenium has been used as a linker for alkenes in two ways (a) as an oxidant-sensitive linker (selenoxides readily undergo [5-elimination at room temperature Entries 6-8, Table 3.43 [767-773]), or (b) as a linker cleavable by tin radicals (Figure 3.37 Entries 9 and 10, Table 3.43). The main advantages of selenides as linkers are their stability under a broad variety of (non-oxidizing) reaction conditions, including high temperatures and treatment with acids or bases, and the mild conditions required for their cleavage. 

Elimination of sulfur, selenium, tellurium compounds Selenoxides... 

Diphenyl selenium dichloride, (C6H5)aSeCl2, is formed when diphenyl selenoxide is treated with hydrochloric acid. It crystallises in glistening prisms, M.pt. 179° to 180° C.4 A similar product is obtained when diphenyl selenide is dissolved in an excess of concentrated nitric acid and concentrated hydrochloric acid added.5... 

Diphenyl selenoxide, (C6H5)2SeO.—This oxide may be prepared in several ways (1) Diphenyl selenium dichloride is treated with sodium hydroxide.6 (2) Diphenyl selenium dibromide is allowed to react with sodium hydroxide.7 (3) 7 grams of diphenyl selenide are slowly treated with 10 c.c. of 46 perhydrol. 8 (4) Diphenyl selenoxide... 

Phenyl methyl selenium dihydroxide, (C6H5)(CH3)Se(OH)2.— The dibromide (10 grams) is triturated with a suspension of 12 grams of silver oxide in 100 c.c. of water until the yellow colour disappears. Filtration, evaporation and desiccation yield about 8 c.c. of the hydroxide as a viscous oil. When heated at 100° C. at 15 mm., or at 170° C. at 760 mm., it decomposes, yielding phenyl methyl selenide, diphenyl diselenide and formaldehyde. The formation of formaldehyde is in agreement with the view that phenyl methyl selenoxide may exist in two isomeric forms, which, being unstable, decompose thus ... 

Di-a-naphthyl selenium dibromide, (C10H7)2SeBr2, is prepared in the usual manner. It forms wThite needles, melting at 183° C. with decomposition, soluble in amyl alcohol but best recrystallised from carbon disulphide. The halogen may be removed by alkali, but only di-a-naphthyl selenide results, no selenoxide being isolated as in the preceding cases. 

Treatment of the hydronitrates in aqueous solution with sodium carbonate causes evolution of carbon dioxide. Evaporation to dryness, followed by extraction with alcohol or benzene, then yields oils which are probably the selenoxides. These oils with concentrated hydrochloric acid are converted into white solids, crystallisable from benzene, xylene, alcohol or dry ether. These solids are the dichlorides of the original selenides, and when prepared by this method their melting-points are as follows Phenyl methyl selenium dichloride, M.pt. 122° C. phenyl ethyl selenium dichloride, M.pt. 64° to 65° C. diphenyl selenium dichloride, M.pt. 142° C. 

In another simple procedure, deprotonation of methoxy bis(trimethylsilyl)methane with butyl lithium and addition of the resulting anion to aldehydes induces Peterson elimination (Scheme 27). The product methyl enol ethers could be hydrolysed to the parent acyl silanes with hydrochloric acid-THF or could be treated with electrophiles such as M-halosuccinimides to give a-haloacyl silanes105. Alternatively, treatment with phenyl selenenyl chloride, oxidation at selenium and selenoxide elimination afforded a,/3-unsaturated acyl silanes. 

Recently, Wirth and Uehlin further extended the selenium-based solid-phase assisted chemistry by introducing a new polymer-bound chiral selenium electrophile 29. Regio-and stereoselective 1,2-methoxyselenylation of propenylbenzene gave intermediate adduct 30 which was cleaved by oxidative elimination via the selenoxide to yield the corresponding allylmethyl ether (Scheme 12) [38]. 

Oxidation of A-diethylphosphito to A-diethylphosphono derivatives 151 has been performed using 2-picoline A-oxide, MCPBA, diphenyl selenoxide, or 7-butyl hydroperoxide (TBHP). The latter was selected as the most efficient reagent. Similarly, the N-phosphitylated /3-sultams undergo reactions of oxidative addition of elemental sulfur and selenium giving 2-thio- and 2-selenophosphono /3-sultams 152 and 153, respectively, in satisfactory yields (Scheme 46) <1999HAC61>. 

Ozonation of carbohydrate-based heterocycles containing selenium 111 (or sulfur) afford the corresponding selenoxides 113 (or sulfoxides) <2006JA227>. Low-temperature treatment of the initially formed ozonation products leads to Pummerer-like reactions affording interesting selenosugars 114 (Scheme 7). Thiosugars are formed from the... 

The thermal decomposition (pyrolysis) of alkylaryl selenoxides (selenoxide pyrolysis) to an alkene and an aryl selenic acid Ar—Se—OH often takes place even at room temperature (Figure 4.10). This reaction is one of the mildest methods for introducing a C=C double bond by means of a /3-elimination. The mechanism is described by the simultaneous shift of three electron pairs in a five-membered cyclic transition state. One of these electron pairs becomes a nonbonding electron pair on the selenium atom in the selenic acid product. The Se atom is consequently reduced in the course of the pyrolysis. 

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