Oxone potassium oxidation with

There are other oxidants reported. The combination of m-CPBA and N-me thy I-morpholine-N-oxide is an effective anhydrous oxidant system for enantioselective oxidation with Mn(salen) compounds [224,225]. Dimethyldioxirane is prepared by the reaction of Oxone (potassium monoperoxysulfate) with acetone [317] and is a member of the smallest cyclic peroxide system. It is an active oxidant for a variety of olefins [318,319]. 

It is noteworthy that quick and effective formation of diaryl nitrones can be achieved through oxidation of diaryl imines with Oxone (potassium peroxy-monosulfate) in such media as aqueous solution of NaHCC>3 in acetonitrile or acetone. When oxidized under such conditions, dialkyl or monoaryl imines give oxaziridines (17). Oxidation of 3,4-dihydroisoquinoline (9) with Oxone initially leads to the formation of oxaziridine (10) which is easily transformed into the corresponding 3,4-dihydroisoquinoline A-oxide (11) upon treatment with catalytic amounts of p-toluenesulfonic acid (Scheme 2.4) (18). 

Chiral ketone-catalyzed asymmetric epoxidation has received intensive interest since the first reported by Curci et al. in 1984. The reaction is performed with oxone (potassium peroxomonosulfate) as the primary oxidant which generates the chiral dioxirane catalytic species in situ, which in turn, transfers the oxygen... 

Both isomeric forms of (+)- and (—)-(camphorylsulfonyl)oxaziridines are available by oxidation of the corresponding sulfonimines with buffered potassium peroxymonosulfate (oxone). Since oxidation can only take place from the endo-fa.ce of the C=N double bond due to steric blocking of the exo-face, a single oxaziridine isomer is obtained. The enantiomerically pure sulfonimines can be prepared in three steps in better than 80% yield from inexpensive (+)- and (—)-camphor-10-sulfonic acids. Alternatively they are commercially available200. 

Among the other oxidants, potassium permanganate and Oxone should be mentioned. Oxidation with potassium permanganate occurs most efficiently under PTC conditions (Equation 84) <1996RJ01194, 1999RJ01511, 2000RJ0916, 2003RJ01679>. 

The desilylated products 31 and 32 (Scheme 20) were obtained by the protiodesilylation of a number of thioacylsilane adducts and the corresponding sulfones obtained by oxidation of the cycloadducts with oxone (potassium hydrogen persulfate). Compounds 31 are formally derived from unstable thioaldehydes and the cyclic sulfones 32 from thioaldehyde 5,5-dioxide (sulfenes) (Scheme 20). It should be noted that sulfenes produced by dehydrochlorination... 

In the Shi epoxidation, an oxone (potassium persulfate, KOSO2OOH) in the presence of a fructose-derived catalyst, 7.57, generates epoxides with high enantiomeric excess oxone is best used to oxidize aldehydes to carboxylic acids in the presence of DMF. 

An efficient, high-yield synthesis of A-alkyl and A-aryl oxaziridine by oxidation of aldimines with buffered Oxone (potassium peroxymonosulfate) has been introduced by Hajipour and Pyne (Equation (47)) <92JCR(S)388>. Oxidation of the aldimine is accomplished in aqueous NaHC03/ acetonitrile or acetone affording the oxaziridine within 15-30 minutes in excellent yield (95-98%). The active oxidizing species in acetone and acetonitrile are thought to be dimethyldioxirane and peroxyimidic acid [MeC(OOH)=NH), respectively. 

Recent work with main group catalysts has concentrated on the use of Oxone (potassium peroxymonosulfate) as co-oxidant with organic ketone derivatives. Shing et al. have described an arabinose ketone catalyst containing a tuneable butanediacetal functionality (Fig. 1.2e) which can be used for asymmetric epoxidation with up to 90% ee [198]. The group of Shi reports on a range of ketones bearing... 

The first synthesis of acetylenic sulfonate 72 was achieved by MCPBA oxidation of sulfinate 68 a to 71, followed by potassium fluoride desilylation, in 90% overall yield. However, to our surprise, the triisopropylsilyl-protected acetylenic sulfinate 68 b resisted oxidation with the oxidants we tried, including MCPBA, oxone, H202/Se02, and Ru04 generated from RuCl3/NaI04 [37],... 

Dioxiranes for alkene epoxidation may be prepared in situ from a catalytic amount of a ketone and Oxone (potassium peroxymonosulfate triple salt). )V,)V-Dimethyl-and A, A -dibenzylalloxans (20a) and (20b) (Figure 3) have been prepared and used as novel dioxirane catalysts for the epoxidation of a range of di- and tri-substituted alkenes in good to excellent yield. H2O2 (rather than the usual Oxone) has been successfully used as primary oxidant in asymmetric epoxidations with Shi s fructose-derived ketone (21) in acetonitrile. The ketone is converted into the dioxirane, which is responsible for epoxidation and the active oxidant responsible for dioxirane formation is proposed to be peroxyimidic acid formed by combination of H2O2 with acetonitrile. ... 

Works on the oxidation of uric acid has unequivocally established the triazine structure > ° (9) of oxonic acid. This is further confirmed by the straightforward synthesis described by Piskala and Gut. ° The reaction of biuret (11) with potassium ethyloxalate yielded a potassium salt (24), that with ethyl oxamate, the amide of oxonic acid (25). Both these compounds were converted to 5-azauracil. An analogous reaction with diethyloxalate which should produce an ester of oxonic acid resulted in a mixture of urethane and parabanic acid, however. 

Oxone is a registered trademark of DuPont with potassium peroxymonosulfate KHSOs (potassium monopersulfate) as oxidizing ingredient of a triple salt with the formula... 

Preparative Methods the enantiopure (+)- and (—)-(cam-phorylsulfonyl)oxaziridines (1) and [(8,8-dichlorocam-phor)sulfonyl]oxaziridines (2) are commercially available. They can also be prepared on a large scale via the oxidation of corresponding camphorsulfonimines with buffered Potassium Monoperoxysulfate (Oxone) or buffered peracetic acid. Since oxidation takes place from the endo face of the C=N double bond, only a single oxaziridine isomer is obtained. The precursor camphorsulfonimines can be prepared in 3 steps (>80% yield) from inexpensive (+)- and —yiO-Camphorsulfonic Acids. A variety of (camphorylsul-fonyl)oxaziridine derivatives such as (2)-(4) are also readily available via the functionalization of the camphorsulfonimines followed by oxidation. " ... 

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