Section 2. Hydrogen Peroxide

Keywords Absorption cross section Hydrogen peroxide Hydroxyl radical ... 

Hydrogen peroxide residual measurements. As discussed under the PAA residual measurement section, hydrogen peroxide residuals can be measured using a dipstick. 

Diphenic acid. Phenanthrene upon oxidation in acetic acid solution at 85° with 30 per cent, hydrogen peroxide gives diphenic acid (diphenyl-2 2 -di-carboxyHc acid) no phenanthraquinone is formed under these experimental conditions. The reaction is essentially an oxidation of phenanthrene with peracetic acid. (For another method of preparation, see Section I V,74.)... 

In a 500 ml. three-necked flask, equipped with a mechanical stirrer, thermometer and dropping funnel, place 300 ml. of 88-90 per cent, formic acid and add 70 ml. of 30 per cent, hydrogen peroxide. Then introduce slowly 41 g. (51 ml.) of freshly distilled cyclohexene (Section 111,12) over a period of 20-30 minutes maintain the temperature of the reaction mixture between 40° and 45° by cooling with an ice bath and controlling the rate of addition. Keep the reaction mixture at 40° for 1 hour after all the cyclohexene has been added and then allow to stand overnight at room temperature. Remove most of the formic acid and water by distillation from a water bath under reduced pressure. Add an ice-cold solution of 40 g. of sodium hydroxide in 75 ml. of water in small portions to the residual mixture of the diol and its formate take care that the tempera... 

Oxidation of diphenylcarbazide (Section VII,3) with hydrogen peroxide in the presence of alcohoUo potassium hydroxide affords diphenylcarbazone ... 

Hydroboration-oxidation (Sections 6 11-6 13) This two step sequence achieves hydration of alkenes in a ste reospecific syn manner with a regiose lectivity opposite to Markovnikov s rule An organoborane is formed by electro philic addition of diborane to an alkene Oxidation of the organoborane inter mediate with hydrogen peroxide com pletes the process Rearrangements do not occur... 

Section 16 16 Oxidation of sulfides yields sulfoxides then sulfones Sodium metaper lodate IS specific for the oxidation of sulfides to sulfoxides and no fur ther Hydrogen peroxide or peroxy acids can yield sulfoxides (1 mole of oxidant per mole of sulfide) or sulfone (2 moles of oxidant per mole of sulfide)... 

In Section 4.2.1 it will be pointed out that hydrogen peroxide (Figure 4.1 la) has only one symmetry element, a C2 axis, and is therefore a chiral molecule although the enantiomers have never been separated. The complex ion [Co(ethylenediamine)3], discussed in Section 4.2.4 and shown in Figure 4.11(f), is also chiral, having only a C3 axis and three C2 axes. 

Nucleophilic opening of oxiranes to give ultimately 1,2-diols is usually effected without isolation of the oxirane oxiranation (epoxidation) of alkenes with unbuffered peroxy-ethanoic acid or hydrogen peroxide in methanoic acid (Section 5.05.4.2.2(/)) tends to give monoesters of 1,2-diols (e.g. 53), which can be hydrolyzed to the diols (Scheme 46). 

Mixtures of a nitrile and hydrogen peroxide are of interest in a commercial hydrazine synthesis (Section 5.08.5) (72TL633). 

Deuterioboration of 5a-cholest-2-ene (171), followed by oxidation of the alkylborane intermediate with hydrogen peroxide in the presence of sodium hydroxide, illustrates the application of this method for the preparation of c/5-deuterium labeled alcohols.(For the preparation of tra 5 -deuterium labeled alcohols see section VII-A.) The predominant reaction product is 2a-di-5a-cholestan-3a-ol (172, 1.03 D/mole) which is accompanied by 3a-di-5a-cholestan-2a-ol (173) and other minor products." ... 

Similar hydroxylation-oxidations can be carried out using a catalytic amount of osmium tetroxide with A-methylmorpholine oxide-hydrogen peroxide or phenyliodosoacetate." A recent patent describes the use of triethylamine oxide peroxide and osmium tetroxide for the same sequence. Since these reactions are of great importance for the preparation of the di-hydroxyacetone side-chain of corticoids, they will be discussed in a later section. 

A mixture of A,A-dimethylcyclohexylmethylamine (49.4 g, 0.35 mole. Chapter 2, Section I), 30% hydrogen peroxide (39.5 g, 0.35 mole) and 45 ml of methanol is placed in a 500-ml Erlenmeyer flask, covered with a watch glass, and allowed to stand at room temperature. After 2 hours, and again after an additional 3 hours, 30% hydrogen peroxide (39.5-g portions each time) is added with swirling. The solution is allowed to stand at room temperature for an additional 30 hours, whereupon excess peroxide is destroyed by the cautious addition (swirling) of a small amount of platinum black. Cessation of oxygen evolution indicates complete decomposition of the excess peroxide. 

Certain /9-diketones react in the presence of hydrogen peroxide to give rearranged carboxylic acids. A proposed II) mechanism is shown. In the procedure, the reaction is applied to 2-acetylcyclohexanone (Chapter 9, Section II). 

The iodometric method has the advantage over the permanganate method (Section 10.95) that it is less affected by stabilisers which are sometimes added to commercial hydrogen peroxide solutions. These preservatives are often boric acid, salicylic acid, and glycerol, and render the results obtained by the permanganate procedure less accurate. 

Determination of sulphite by oxidation to sulphate and precipitation as barium sulphate Discussion. Sulphites may be readily converted into sulphates by boiling with excess of bromine water, sodium hypochlorite, sodium hypobromite, or ammoniacal hydrogen peroxide (equal volumes of 20-volume hydrogen peroxide and 1 1 ammonia solution). The excess of the reagent is decomposed by boiling, the solution acidified with hydrochloric acid, precipitated with barium chloride solution, and the barium sulphate collected and weighed in the usual manner (Section 11.72). 

Conversion of thiosulphate to sulphate and determination as barium sulphate Discussion. Thiosulphates are oxidised to sulphates by methods similar to those described for sulphites (Section 11.74), e.g. by heating on a water bath with an ammoniacal solution of hydrogen peroxide, followed by boiling to expel the excess of the reagent. The sulphate is then determined as barium sulphate, BaS04. 

A — 78 rC solution of (Z)-2-butenyl(diisopinocampheyl)borane (theoretically 25 mmol prepared from ( + )-a-pinenc as described in Section 1.3.3.3.3.1.1.1.) is treated with 2.0 mL (35 mmol) of acetaldehyde (added dropwise). The mixture is stirred for 3 h at — 78CC and is then treated with 18.3 mL (55 mmol) of 3 N sodium hydroxide and 7.5 mL of 30% hydrogen peroxide solution. This mixture is refluxed for 1 h. The organic phase is separated, washed with water and NaCl and dried over MgS04. The filtrate is carefully fractionated yield 75% d.r. (syn/anti) >99 1 (GC) bp Torr 90% ee. 

The Tf- CF system is preferred over Fenton s reagent because Ti4 is a less powerful oxidizing agent than Fc5+ and the above mentioned pathway and other side reactions are therefore of less consequence.252 Much of the discussion on redox initiation in Section 3.3.2.6.1 is also relevant to hydrogen peroxide. 

Common components of many redox systems are a peroxide and a transition metal ion or complex. The redox reactions of peroxides are covered in the sections on those compounds. Discussion on specific redox systems can be found in sections on diacyl peroxides (3,3.2.1.5), hydroperoxides (3,3.2.5) persulfate (3.3.2.6.1) and hydrogen peroxide (3.3.2.6,2). 

As an oxidant, hydrogen peroxide may be used either alone or in the presence of a catalyst. Such reactions are often carried out using acetic acid as a solvent. These latter reactions strictly involve oxidation by peracetic acid and will be dealt with in the next section. 

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