Ozone is the perfect killer of bacteria, virus, mold, and a host of other things that are worse than Ozone. Still, it is corrosive, but once it has oxidized whatever it touches, what's left is oxygen. Don't you remember how good the air is after a lightning storm? Like anything in excess, it can be dangerous. I couldn't kill the mold in between the wall panels of my boat when I had a water accident, but the ozone did. Here's an internet explanation.
Ozone Oxidation is Nature’s Sanitation Powerhouse
Ozone (O3) is a form of oxygen that has one more oxygen atom than the atmospheric oxygen (O2) we breathe. It’s this third oxygen atom that makes the ozone molecule so unstable, which is the key to its oxidizing power. Since ozone is unstable, it has a fairly short half-life under normal conditions, so it has to be produced and supplied continuously to a disinfection process.
This is where DEL Ozone comes in: DEL systems manufacture and deliver ozone in exactly the right quantities to provide the needed disinfection power for a given application.
How is Ozone Generated?
The chemical reaction that results in ozone is pretty simple. Ozone is a form of oxygen that is created when electrical energy breaks apart an ordinary oxygen molecule (O2) starting a chemical reaction that results in ozone (O3).
Electrical energy breaks the ordinary O2 molecule into two O1 atoms
The free oxygen atoms unite with other O2 molecules to produce ozone
(O1) + (O2) = (O3)
Ozone is an unstable molecule because the 3rd oxygen atom is connected to the other two atoms with a weak bond (symbolized by the single line in the diagram). The weak bond is why ozone is such a powerful sanitizer, as shown below.
DEL Ozone systems duplicate this process with advanced technology that produces ozone safely, reliably, in controlled amounts, and effectively managed to achieve our disinfection objectives.
How Does Ozone Work?
Once a DEL system has delivered ozone through a disinfection system, it cleans the target water or produces ozone-enriched water to sanitize a surface through ozone oxidation.
The unstable third oxygen atom can combine with organic and inorganic molecules to destroy or change them through oxidation. This process happens almost instantaneously. For example, ozone in a swimming pool will kill Cryptosporidium parvum practically on contact, whereas chlorine in normal pool concentrations would take hours to kill it. Like chlorine, ozone is “used up” in the oxidation process, and has to be re-supplied.
Ozone oxidizes a very large range of other substances. In a pool, these organic molecules can be viruses, bacteria, fungi, yeast, oils, organic chloramines, etc., and inorganic molecules can be dissolved metals such as iron, copper and manganese, and inorganic forms of chloramine. On a food preparation surface, or on the food itself, the target organism might be Salmonella, Listeria, E. coli or any number of other dangerous microorganisms. In hospital or long-term care laundry, the ozone kills the dangerous antibiotic resistant staph bacteria (MRSA) that can be carried on clothing or bedding.
The chemical process of ozone oxidation is relentless. It continues until the ozone is completely destroyed (actually, it is “reduced” in the process of “oxidizing” other substances). When this beneficial third unstable atom completes its oxidizing duties, it leaves behind only the familiar oxygen molecule like the ones in the air we breathe, O2.