How Gas Chromatography Work
In chromatography, one gas moves over the sample substance. The moving gas is known as the mobile phase, and it's usually an inert gas, such as nitrogen or helium. As the mobile phase passes over the substance, it separates out into its component parts. Since accuracy is key, it's vital that the moving gas not react with the substance being analyzed. For this reason, inert gases are recommended for gas chromatography.
Gas chromatography takes place within a special machine, known as a gas chromatograph machine. The substance being studied is injected into the chromatograph with a syringe, then the material is heated to the vapor stage. The carrier gas -- e.g. nitrogen -- is then added to the chromatograph to push the sample up the central column. As the substance being analyzed passes up the column, it's absorbed by the carrier and then separated into its distinct components. The components emerge from the column and pass through a detector, where they are identified and noted on a chart.
When the process is complete, every part of the mixture is identified. At this point, for instance, a forensic scientist will have the raw data needed to analyze evidence found at the crime scene. While television shows may portray the process as instant, it's often time-consuming.
Within the medical marijuana industry, scientists are using gas chromatography to test for pesticide residue in cannabis. While the medical marijuana industry is still young, and pesticide levels are not heavily regulated, industry leaders expect this to change as the marijuana industry grows. Thus, the use of gas chromatography to check for pesticides will grow too.
Whenever gases is used in the chromatography process, there's a potential for gas leaks, whether from the supply lines, storage tanks, or from the chromatograph itself. Nitrogen gas displaces oxygen. If nitrogen were to leak, air levels would become deficient of oxygen and employees could suffer health problems.
Since nitrogen gas has no color or odor, there is no way for lab staff to tell that the gas has leaked. The best way to safeguard the lab is with an oxygen monitor.
Risks of breathing oxygen deficient air include dizziness, fatigue, unconsciousness, and death via asphyxiation. All it takes is a couple breaths of air to experience adverse health effects.
Since there is no way to tell whether a leak has occurred, it's necessary to use an oxygen sensor to track oxygen levels at all times. The oxygen monitor or sensor measures oxygen and only reacts when levels fall below a predefined threshold. Oxygen sensors from PureAire have alarms for oxygen levels of 18 percent and 19.5 percent, for instance.
The oxygen deficiency monitor includes a flashing light and loud alarm, so that staff and passerby receive prompt notification of the leak. When the alarm goes off, employees can vacate the premises and contact emergency personnel.
Given the serious risks posed by a nitrogen gas leak, it's important to use oxygen deficiency monitors anywhere inert gases are stored or used.
PureAire is an industry leader when it comes to oxygen monitors. O2 monitors from PureAire are designed for long-lasting and maintenance-free use. They feature a zirconium sensor, which lasts for 10-plus years without calibration. PureAire's monitors can handle temperature changes, barometric shifts, and even freezing temperatures. Learn more about PureAire's monitors and how they promote safety at
www.pureairemonitoring.com.
Source: http://www.explainthatstuff.com/chromatography.html
Keywords: Gas Chromatographers, gas chromatography, oxygen monitor, oxygen deficiency monitor, O2 monitor, gas monitor, nitrogen, argon, helium, PureAire, PureAire monitoring systems