Gases

 


Pollutants - Gases - NO2

MONITORING OPTIONSPRICINGABOUT NO2
MONITORING OPTIONS

AirQuality Limited can offer a variety of monitoring options for the monitoring of NO2 including:

  • NO2 Chemiluminescent analyser
  • NO2 Gas Sensitive Semiconductor
  • NO2 Electrochemical Sensor
  • NO2 Passive sampler

More detail on each of these options is shown below:

NO2 Chemiluminescent Analyser
The Chemiluminescent analyser is a reference standard instrument which can meet the requirements of AS 3580.5.1-2011 : Determination of oxides of nitrogen – Direct-reading instrumental method.
The correct operation of this instrument requires a temperature controlled enclosure with a calibration unit and compressed span gas.

NO2 Gas Sensitive Semiconductor
The AirQuality Gasmote-NO2 gas sensitive semiconductor (GSS) technology uses advanced heated metal oxide technologies in combination with data-logging, communications and global positioning systems

  •  Capable of high quality indicative NO2 measurement
  •  Continuous measurement, automated data up-load
PRICING

Pricing is dependent upon:

  • The length of time you wish to monitor for
  • The type of equipment you wish to use
  • Whether you wish to purchase or rent the monitoring instrumentation
  • The level of data validation and reporting
  • Whether an instrument enclosure is required
  • Whether mains or solar powered options are required
  • Whether wind speed and direction also need to be measured

Our clients tell us that we offer very competitive quotes for both the supply and operation of these instruments.

Contact us today for an obligation free quote!

ABOUT NO2

Current scientific evidence links short-term NO2 exposures, ranging from 30 minutes to 24 hours, with adverse respiratory effects including airway inflammation in healthy people and increased respiratory symptoms in people with asthma.

Also, studies show a connection between breathing elevated short-term NO2 concentrations, and increased visits to emergency departments and hospital admissions for respiratory issues, especially asthma.

NO2 concentrations in vehicles and near roadways are appreciably higher than those measured at monitors in the current network. In fact, in-vehicle concentrations can be 2-3 times higher than measured at nearby area-wide monitors. Near-roadway (within about 50 meters) concentrations of NO2 have been measured to be approximately 30 to 100% higher than concentrations away from roadways.

Individuals who spend time on or near major roadways can experience short-term NO2 exposures considerably higher than measured by the current network. NO2 exposure concentrations near roadways are of particular concern for susceptible individuals, including people with asthma asthmatics, children, and the elderly.

The sum of nitric oxide (NO) and NO2 is commonly called nitrogen oxides or NOx. Other oxides of nitrogen including nitrous acid and nitric acid are part of the nitrogen oxide family. While EPA’s National Ambient Air Quality Standard (NAAQS) covers this entire family, NO2 is the component of greatest interest and the indicator for the larger group of nitrogen oxides.

NOx react with ammonia, moisture, and other compounds to form small particles. These small particles penetrate deeply into sensitive parts of the lungs and can cause or worsen respiratory disease, such as emphysema and bronchitis, and can aggravate existing heart disease, leading to increased hospital admissions and premature death.

Ozone is formed when NOx and volatile organic compounds react in the presence of heat and sunlight. Children, the elderly, people with lung diseases such as asthma, and people who work or exercise outside are at risk for adverse effects from ozone. These include reduction in lung function and increased respiratory symptoms as well as respiratory-related emergency department visits, hospital admissions, and possibly premature deaths.

Emissions that lead to the formation of NO2 generally also lead to the formation of other NOx. Emissions control measures leading to reductions in NO2 can generally be expected to reduce population exposures to all gaseous NOx. This may have the important co-benefit of reducing the formation of ozone and fine particles both of which pose significant public health threats.