****!!!! "Chlorine Dioxide Test Strip monitors chlorine dioxide levels, including residuals from 0-500ppm in increments of 0, 10, 25, 50, 100, 250, and 500ppm." ***** "The Chlorine Dioxide 0-500 test strips will react to free chlorine solutions, in fact this is how we check the color chart. Only the Low Level Chlorine Dioxide 0-10ppm has an inhibitor for free chlorine. The Chlorine Dioxide 0-10ppm test strips include an inhibitor for free chlorine up to 4 ppm free chlorine."

"Chlorine Dioxide is a WONDERFUL disinfectant, but, if you know the first thing about it, you know that its concentration in solution wanes rather rapidly. It's easy to make in the lab or kitchen--jut a little Sodium ChlorITE, a tad of bleach (increases yield) and either muriatic or citric acid ("sour salt" in your Kosher section). I keep a little bottle handy for scrapes and scratches--and it kills cold sores DEAD, but how to know whether you need to replace? Instant answer with these stripts!"

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(1) sulfuric acid is added into sodium chloride solution to obtain mixed solution with the sulfuric acid concentration being 1 to 10 mol.L and the sodium chloride concentration being 1 to 5 mol.L; (2) the mixed solution is added into a reactor containing zinc sulfide ore for taking reaction, and chlorine dioxide and little chlorine gas are produced through the reaction; and (3) mixed absorption liquid formed by alkali liquor and hydrogen peroxide are added into an absorber, wherein the mol ratio of the alkali liquor, the hydrogen peroxide and the sodium chlorate in the reactor is (0.5-1): (0.5-0.8):1, gas produced in the reactor is sent into the absorber, the temperature is maintained at -5 to 10 DEG C, and the reaction lasts 0.5 to 2 hours. The zinc sulfide is utilized and is subjected to two-step reaction so that the conversion rate of converting raw materials of the sodium chlorate into sodium chlorite can be as high as more than 97 percent, and the purity of the obtained sodium chlorite is very high.

"composition of matter comprising a solid form of chlorine dioxide complexed with a cyclodextrin. The concentration of chlorine dioxide in said solid form is greater than approximately 5.8 percent by weight"

In this study the interaction of the preservative sodium chlorite with unsaturated lipids and glutathione was investigated, in comparison with peroxides, sodium hypochlorite, and benzalkonium chloride. The aim was to determine whether the action of sodium chlorite could involve membrane lipid damage …

Sodium hypochlorite and sodium chlorite are commonly used as disinfectants, and understanding the mechanisms of microbial resistance to these compounds is of considerable importance. In this study, t...

****!!!!***!!** "Glutathione levels did not correlate with the measured TAC values, despite this being the most important non-enzymatic intracellular antioxidant molecule. The results indicate that the isolated measurement of TAC does not give a clear picture of the ability of a given Candida sp. to respond to oxidative stress."

In this study the interaction of the preservative sodium chlorite with unsaturated lipids and glutathione was investigated, in comparison with peroxid…

"In contrast to its responses to hydrogen peroxide and paracetic acid, KatE1 was not the primary scavenger of chlorine dioxide in these V. parahaemolyticus strains."

{Includes optimal ingredients} Patent application abandoned.

***!!!!** {Includes chlorine dioxide concentration levels that oxidize various medicines} "The formation of undesirable by-products can be controlled by minimizing the dose of ClO2 and applying post-treatment using, for example, ferrous iron (Fe2+) or sulfite (SO3 2-), which reduces ClO2 and chlorite residuals to chloride [22,23]. The removal of ClO2 and chlorite residuals allows higher levels of ClO2 to be used for treatment providing effective micropollutant removal. " "Wastewater effluents were collected from two wastewater treatment plants in Sweden, one with extended nitrogen removal (low COD) and one without (high COD). "

Chlorine dioxide (ClO2) has been promoted as an alternative disinfectant because of its high disinfection efficiency and less formation of organic dis…

"ProOxine®AH Now Claims Efficacy Against PED" "OXINE® Approved for Horticulture Applications... eliminates most microbial issues at grower facilities at doses as low as 1 ppm to 5 ppm." "Keeper® Technology Now Certified Organic" "anti-microbial agent for the Red Meat, Poultry and Post Harvest Industries" “The issuance of Organic Certification now allows the organic producer the same level of protection employed by traditional producers.” “The active component in Keeper is Acidified Sodium Chlorite (ASC) – a powerful antimicrobial with adequate residual effect. After its intended technical effect, ASC breaks down into table salt. This is the fundamental premise of Keeper® approval as an organic material,”

{Includes 2 videos on benefits of chlorine dioxide use in nursing homes} "...surface disinfection of high-traffic consumer and professional spaces.  For over a decade, AET has achieved exemplary treatment results in the auto/boat/RV industries, athletic facilities, healthcare Systems, restaurants, and commercial/residential areas."

****!!!!****!!!!**** "New compositions and methods are disclosed for decontaminating surfaces and enclosures that avoid problems such as salt deposits, corrosion and condensation that accompany the use of known methods. The process involves the use of chlorine dioxide solutions prepared by passing dilute chlorine gas over solid granular sodium chlorite to produce chlorine dioxide gas which is then collected in solution." "...mixing the gas with a carrier gas to produce a gas stream containing chlorine dioxide and disinfecting an enclosure. The gas can be produced by releasing chlorine dioxide gas from an aqueous chlorine dioxide solution containing less than 10% by weight of any of hydrochloric acid, hypochlorite ion, hypochlorous acid, or sodium chloride or it can be produced directly for use, as described above. When solutions are used it is preferred that they contain no more than 5%, or more preferably 2.5%, [etc] of... contaminants." "[Anthrax treatment:] As chlorine dioxide gas is stripped out of solution in this method, micro-droplets of solution became entrained in the resulting gas stream and were carried into the building. These droplets deposited a corrosive mixture of water and contaminants throughout the building space causing severe corrosion and other damage. Even where there was no corrosion, salt deposits had to be removed after decontamination was complete. In addition, the solution became hot as it was produced and when pumped into the stripper column (material transfer device) and contacted with air heated by the blowers, the gas stream was warm and humid. This resulted in severe condensation within the building when the warm, humid air contacted cooler air and cooler surfaces in the building. Large mechanical cooling units were used to partially dehumidify the air but a method was never found to control humidity and chlorine dioxide gas concentration simultaneously."

"Chlorine dioxide is unaffected by pH over a wide range, uniquely effective at destroying established biofilm, free of toxic or carcinogenic by-products, and capable of removing bio-contaminants from Anthrax to zebra mussels. In fact, chlorite and chlorate, two of chlorine dioxide’s primary by-products, both break down into chloride, or simple, harmless salt."

"Published test results demonstrate that pure chlorine dioxide supplied in ready-to-use aqueous solution can remove bio-fouling and prevent its regrowth on Thin Film Composite (TFC) membranes and filters in reverse osmosis or ultra-filtration system without damage to membranes. Previous results showing membrane damage from chlorine dioxide are believed to be caused by impurities such as chlorine or chlorous acid in chlorine dioxide made at the point of use. These impurities are not present in CDG Environmental products."

"it has become the oxidizer of choice to solve many problems in potable water, including: --Preliminary oxidation to reduce the formation of chlorinated hydrocarbons (THMs and HAAs) during chlorination --***Oxidation of dissolved manganese and iron to form insoluble manganese or iron, which can be removed. Chlorine dioxide oxidizes manganese to its insoluble state without going all the way to soluble permanganate***... --Inactivation of Giardia and Cryptosporidium (parasites) --Secondary disinfection of water systems to control/remove biofilm and Legionella"

"At the heart of the GAS:SOLID™ chlorine dioxide generation process is the reaction between chlorine gas and SAF-T-CHLOR™ thermally stable solid sodium chlorite. This reaction produces no by-products—just pure chlorine dioxide gas (in air or nitrogen), free of chlorite ion, chlorate ion, perchlorate ion or molecular chlorine" "The CDG GAS:SOLID™ system uses SAF-T-CHLOR™ thermally stable solid sodium chlorite. SAF-T-CHLOR™ sodium chlorite is thermally stable, even on extreme localized heating (1,000° C) for a prolonged period (10 minutes). This is in stark contrast to conventional solid sodium chlorite: even on transient "

Until recently, chlorine used to be an important chemical in bleaching process in paper industry, but as a result of environmental concerns, it is being replaced by chlorine dioxide. However, chlorine dioxide is more corrosive in certain conditions. Plant personnel, therefore need to better understand the reactions taking place in the changed media and search for more resistant materials. It is with this in mind that the present work was undertaken. The paper reports the electrochemical polarisation measurements performed on stainless steels 316L, 317L, 2205 and 254SMO in chlorine dioxide solutions to observe localised corrosion. The results have been analysed with reference to Pourbaix diagrams, taking into account the various chemical species present in the bleach solutions. Conclusions drawn from electrochemical tests have been compared with those from long‐term laboratory and plant tests. Materials options are proposed on the optimal choice of materials for bleach plants, in a context of probable corrosion performance, capital cost and mechanical strength.

"applications in which soil residues are frequent." "One sanitizer was an acidified solution of dilute sodium chlorite at pH 2.7; the other sanitizer was dilute chlorine dioxide (about 15 ppm) in tap water. Stainless steel types 304 and 316 corroded rapidly when exposed to the acidified chlorite solution. Chlorine dioxide near neutral pH 7.2 was noncorrosive to both type 304 and 316 stainless steels at a concentration of 100 ppm during 10 d of continuous exposure. This concentration is well above the typical use Concentration of 15 ppm; typical use time span is 15 min."

"It is produced by reaction between chlorine dioxide and excess ozone:"

Heme b containing chlorite dismutase (Cld) catalyses the conversion of chlorite to chloride and dioxygen which includes an unusual OO bond formation. …

Chlorite dismutase (Cld) is a heme-dependent enzyme that catalyzes the decomposition of toxic chlorite (ClO2(-)) into innocuous chloride and O2. In this paper, using the hybrid B3LYP density functional theory (DFT) method including dispersion interactions, the Cld reaction mechanism has been studied with a chemical model constructed on the X-ray crystal structure. The calculations indicate that the reaction proceeds along a stepwise pathway in the doublet state, i.e. a homolytic O-Cl bond cleavage of the substrate leading to an O-Fe(heme) species and a ClO˙ radical, followed by a rebinding O-O bond formation between them. The O-Fe(heme) species is demonstrated to be a low-spin triplet-state Fe(IV)=O diradicaloid. A low-spin singlet-state Fe(IV)=O is much less stable than the former, with an energy difference of 9.2 kcal mol(-1). The O-Cl bond cleavage is rate-limiting with a barrier of 10.6 kcal mol(-1), in good agreement with the experimental reaction rate of 2.0 × 10(5) s(-1). Furthermore, a heterolytic O-Cl bond dissociation in the initial step is shown to be unreachable, which ensures the high efficiency of the Cld enzyme by avoiding the generation of chlorate byproduct observed in the reactions of synthetic Fe porphyrins. Also, the pathways in the quartet and sextet states are unfavorable for the Cld reaction. The present results reveal a detailed mechanism III (defined in the text) including an interesting di-radical intermediate composed of a low-spin triplet-state Fe(IV)=O and a ClO˙ radical. Compared to a competitive heterolytic Cl-O cleavage in synthetic Fe porphyrins, the revelation of the domination of homolysis in Cld indicates not only the high efficiency of enzyme, but also the sensitivity of a heme and the significance of the enzymatic active-site surroundings (the His170 and Arg183 residues in the present case), which gives more insights into heme chemistry.

1985