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The hypochlorous acid (HOCl) further breaks down:
The pH of the solution determines the relative proportions of hypochlorous acid (HOCl) and hypochlorite (OCl-). At 0C, there is half HOCl and half OCl- at pH 7.9. At lower pH there is relatively more HOCl and relatively better antimicrobial activity.

In fact, there is a better way to measure the activity of oxidizing compounds. Since they all kill microbes through oxidation, it is possible to measure their anti-microbial activity by measuring the oxidation-reduction capacity of the water. This is measured as millivolts (mV) of electrical potential in the water. Many years of research has shown that if the oxidation-reduction potential is greater than 650 mV, most pathogens will be killed on contact. By constantly maintaining the potential above 650 mV, we can be assured that our wash water is clean without having to measure the amount of sanitizer in the water. There are automated systems commercially available that monitor the electrical potential of the water and inject sanitizer (and sometimes acid) into the water, as needed, to stay above 650 mV. This is a more direct way to monitor wash water cleanliness than traditional measures of ppm total chlorine, for example.

AquaFew AC ORP (Oxygen Reduction Potential) level is 1000+ and pH level can be anywhere from 2.2 to 3.0. They level of pH is set for certain applications.

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A Few Words About Chlorine Chemistry. Chlorine is very reactive and so combines with almost any oxidizable substrate to form secondary compounds. In addition, the dissociation of chlorine in water depends on the form of chlorine used, the pH of the water and the amounts and kinds of organic materials present in the water. All of these factors make the interactions of chlorine in water complex and hence the widespread confusion within the industry on how best to use chlorine. Terms such as total chlorine, free chlorine, residual chlorine, chlorine gas, hypochlorite and hypochlorous acid are enough to confuse the most dedicated sanitation manager. Of the many possible forms of chlorine, hypochlorous acid is the really good disinfectant. Thus, in our management of chlorine, we want to maximize the hypochlorous acid and minimize all the other forms of chlorine. When either chlorine gas (Cl2) or hypochlorite solution (NaOCl) or solid Ca(OCl)2 are added to water, the following reactions occur:

The hypochlorous acid (HOCl) further breaks down:
The pH of the solution determines the relative proportions of hypochlorous acid (HOCl) and hypochlorite (OCl-). At 0C, there is half HOCl and half OCl- at pH 7.9. At lower pH there is relatively more HOCl and relatively better antimicrobial activity.

When chlorine gas dissociates, one of the products is H+ or hydrogen ions. These cause the pH to be lowered slightly which improves the chlorine activity. When hypochlorites dissociate, one of the byproducts is OH-, which raises the pH slightly and reduces the chlorine activity. These effects will be greatest in unbuffered water.

What Is Free Chlorine? Free chlorine (or free active chlorine) refers to the total amount of elemental chlorine gas (Cl2), hypochlorous acid and hypochlorite. Total chlorine, in turn, would also include NaOCl, Ca(OCl)2, chloramines, chloroform and other less active forms. At high pH the free chlorine content can be high, but it will mostly be in the form of hypochlorite and so will be ineffective. The same free chlorine content at lower pH will be much more effective. Thus, measuring free chlorine does not assure efficacy. It is crucial that the pH be below 7.5 so that the majority of the free chlorine is active hypochlorous acid.

What Chlorine Does and Does Not Do. Chlorine is a very good antimicrobial and sanitizing agent. In high enough concentrations, it kills bacterial cells on contact. It is less effective against bacterial and fungal spores but, given enough time and concentration, chlorine will kill spores too. Chlorine can help prevent buildup of biofilms on machinery and can prevent proliferation of microorganisms in wash water. In fact, the greatest benefit of chlorine in most operations is that it keeps the wash water clean so that product does not become contaminated by microbes in the water. Chlorine is not a sterilant. While it can reduce microbial populations on produce, it will not make produce microbe-free. Chlorine has virtually no penetrating action so it is not effective against internal fungi and bacteria. While chlorine can help prevent postharvest disease by keeping the wash water clean, it will not cure diseased product that has already been infected in the field or during processing.
Chlorine has no residual effect so it will not prevent recontamination after washing. Prevention of recontamination must be accomplished through care in handling and through a comprehensive program of worker and facility sanitation.
Chlorine will not confer any benefits if the wash water is not kept relatively clean and free of organic matter, if the pH of the water is high, if the concentration of active chlorine (hypochlorous acid) is not high enough, and if the chlorine is not allowed to contact the product for enough time. If the chlorination system is properly monitored and operated, chlorine can be an important and useful part of product sanitation.

Alternatives to Chlorine. Alternatives to hypochlorite are available for produce water disinfestation. Chlorine dioxide is not approved for use on cut produce but can be used in wash water or in contact with intact produce. Chlorine dioxide is less sensitive to pH and organic mater than is hypochlorite and is active at lower concentrations. Chlorine dioxide generation systems are generally more expensive than hypochlorite. Sodium hypobromite (bromine based) is also approved for use in place of sodium hypochlorite but I am not aware of any use of bromine for water sanitation in the produce industry. Ultraviolet light systems are available for water sterilization as well as for use on produce surfaces. Ultraviolet light leaves no chemical residues and is not affected by water chemistry. However, it is only surface active and so requires clear water to be effective. Ozone is approved for use as a water sterilant but not for use directly on product. Ozone is a very good sterilant but is subject to environmental and worker exposure regulations.
Activities and environmental sensitivities of wash water sanitizers.

How Do We Measure Sanitizer Activity? Of the five classes of sanitizing compounds listed above, four are oxidizers. That is, they kill microorganisms through oxidation reactions. Ultraviolet light kills microbes through physical disruption of their genetic material, DNA.

The various oxidizing compounds have been measured in different ways; free chlorine, total chlorine, available chlorine, parts per million of ozone or chlorine dioxide, percent peroxyacetic acid. What we are really interested in knowing is not how much sanitizer is present, but rather how effectively the sanitizer is killing microorganisms. This could be measured by taking water samples to a lab and counting the microorganisms in the water. This would be slow and expensive.

In fact, there is a better way to measure the activity of oxidizing compounds. Since they all kill microbes through oxidation, it is possible to measure their anti-microbial activity by measuring the oxidation-reduction capacity of the water. This is measured as millivolts (mV) of electrical potential in the water. Many years of research has shown that if the oxidation-reduction potential is greater than 650 mV, most pathogens will be killed on contact. By constantly maintaining the potential above 650 mV, we can be assured that our wash water is clean without having to measure the amount of sanitizer in the water. There are automated systems commercially available that monitor the electrical potential of the water and inject sanitizer (and sometimes acid) into the water, as needed, to stay above 650 mV. This is a more direct way to monitor wash water cleanliness than traditional measures of ppm total chlorine, for example.

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