At concentrations of several ppm, and at room temperature, the half-life of ozone due to decomposition is of the order of 1 day. Only at temperatures above 500oC does the thermal decomposition reaction become important. Thus, in the very hot region adjacent to the welding arc this decomposition reaction can be very important, and the net quantity of ozone emitting from the arc can be greatly affected.
Decomposition can also be accelerated by contact with surfaces and catalysts.
Experiments have shown that the ozone concentration measured during the first minute of welding immediately reaches a peak, which decays after a few seconds, and then remains constant at a background level of between 40% and 60% of the peak value.

Ozone is a highly toxic, chemically active gas that is definitely hazardous to human life. Due to its highly oxidising nature, ozone reacts with virtually anything, including the tissue inside the respiratory passages and lungs, producing cell damage and leakage through the cell membranes.
It should be noted that cell damage due to ozone inhalation is permanent and irreversible.

Health and Safety regulations in each country set maximum permissible concentrations of ozone to control exposure of people at work. In America these are called Threshold Limit Values (TLV), while in Europe they are known as Occupational Exposure Limits (OEL). These limits are Time Weighted Averages (TWA) and so take into account the amount of time for which people are exposed.

In order to assess the potential risk, it is necessary to determine whether ozone is present during and after the welding operation, and in what concentration.
Measurement of ozone in breathing zones, and elsewhere, on the shop floor, is normally carried out by means of chemical reaction tubes, detector tubes, that give a single instantaneous reading.
Ozone meters require accurate calibration and also need a suitable filtration system to remove particulate fume.
Once the ozone concentration has been measured, it is compared with the current limit and control measures, if appropriate, put in place. Only suitably qualified and experienced personnel should carry out such measurement, assessment and interpretation.

Due to the fact that ozone can be formed some distance from the arc as well as close to it, control of exposure and removal of ozone from the workplace can be difficult.
Use of local fume extraction equipment will take some ozone away with the particulate fume but is unlikely to completely solve the problem.
Because of the difficulties with extraction, control of exposure to ozone from welding is often achieved by use of personal respiratory protection for welders, and any other workers at risk, in conjunction with local fume extraction to remove other fume hazards from the area.