Oxone

The triple salt is produced via peroxysulfuric acid, which is generated in situ from sulfuric acid (oleum) and hydrogen peroxide and with potassium hydroxide. The purity of Oxone can be determined by iodometric titration. Heavy metal salts catalyze the decomposition of the title compound, based on reporting on its triple salt formulation. An estimated 43-45% of it, by weight, of which 5.2% active oxygen is theoretically possible, and 4.7% was typically observed. In 2012, a review was reporting the estimate to be "about 50% per mole" of triple salt. == Uses ==

Underlying the uses of Oxone is the highly positive oxidation potential for peroxymonosulfate, which is +1.81 V. Cleaning Oxone-type products are used for oxidative processes that result in decomposition of organic contaminants, and therefore in cleaning, whitening, and disinfection. For instance, it can be used to whiten materials used in dental health practices, to clean materials in the manufacture of microelectronics, and decontaminate recreational water pools. Use of formulations containing the title compound in pool water quality management can interfere with determinations of chlorination assay, using a standard ferrous ammonium sulfate, N,N′-diethyl-p-phenylenediamine (FAS-DPD) method, if added reagents and steps are not followed to neutralise the KMPS (potassium monopersulfate / peroxymonosulfate). Preparative chemistry Oxone is a versatile oxidant in organic chemistry. It oxidizes terminal alkenes to epoxides. It converts internal alkenes into two equivalents of carboxylic acid. Oxone convert aldehydes to carboxylic acids. When such reactions are conducted in the presence of alcoholic solvents, the corresponding esters may be obtained. Oxone converts ketones to dioxiranes, which can be used for diverse oxidations in organic synthesis. and in the oxidation of other unsaturated functionalities, heteroatoms, and even some alkane C-H bonds. Oxone is used in the production of some organic periodinanes, notably the oxidation of 2-iodobenzoic acid to 2-iodoxybenzoic acid (IBX). Peroxymonosulfate-driven conversions can be used with sulfides and selenides to prepare sulfones and selenones, with anilines and amino sugars to provide nitro compounds, oximes to provide nitro compounds (in aqueous buffered conditions) or to return the parent carbonyl compounds (in the presence of alumina, with microwave heating), primary and secondary amines to provide hydroxylamines (using adsorbed Oxone) or N-nitrosation products (in the presence of sodium nitrite), pyridines and tertiary amines to provide amine oxides, and phosphorus(III) compounds to provide phosphono-compounds largely retaining configuration at phosphorus (with comparable outcomes when a sulfur or selenium atom replaces the phosphorus(III) lone pair). and the synthesis of fluoromethyl phenyl sulfone, a reagent used in the synthesis of fluoroalkenes. ==Further reading==