Monitoring Programs
WBEA Air Monitoring
Ambient Air Monitoring Program
The WBEA has monitored and reported ambient air quality in northeastern Alberta since 1997. As part of its Ambient Air Monitoring Program, the WBEA currently operates 29 ambient air monitoring stations throughout the Regional Municipality of Wood Buffalo (RMWB). The Ambient Air Monitoring Program functions to address multiple objectives and scientific questions, and is conducted through both continuous and time-integrated (non-continuous) sampling methods. The WBEA reports hourly ambient air monitoring data to Alberta Environment and Protected Areas (EPA), as well as provides all air monitoring data online for public access.Learn more
WBEA Deposition Monitoring
Deposition Monitoring Program
The WBEA, through the Terrestrial Environmental Effects Monitoring (TEEM) program, operates an integrated Atmospheric Deposition Monitoring Program to detect possible impacts of air contaminants on forest health, which is comprised of three monitoring program components: the Deposition Monitoring program; the Forest Health Monitoring (FHM) program; and the Meteorological Monitoring program.Learn more
WBEA Odour Monitoring
Odour Monitoring Program
The WBEA Odour Monitoring Program (previously the Human Exposure Monitoring Program) is focused on detecting and identifying odour events and odour causing compounds. Currently, the Community Odour Monitoring Program is the focus to collect data on odours in the region.Learn more
Community Based Monitoring
Community Based Monitoring Program
The WBEA collaborates with Indigenous communities within the RMWB on monitoring projects to understand impacts of development on their communities.Learn more
Why Do We Monitor?
The WBEA monitors ambient air quality to provide data to measure health and environmental effects so stakeholders and land users can make informed decisions. The WBEA’s monitoring data and information has numerous applications, including but not limited to:
- Regulatory control and action (e.g., land use planning,emission criteria)
- Determine background and present air quality conditions
- Promote public awareness
- Support early warning systems
- Develop and validate air quality models
- Meet Alberta’s Environmental Protection and Enhancement Act (EPEA) approvals
- Determine dose-receptor relationships
- Document trans-boundary movements
- Identify long-term trends
Types of Monitoring at the WBEA
Continuous Data
Continuous ambient air monitoring uses analyzers that constantly measure the concentrations of different pollutants in the air. All stations also continuously measure temperature, relative humidity, and wind speed and direction. The WBEA's continuous ambient air data is available to everyone.
View Continuous DataTime-Integrated Data
Time-integrated sampling provides more detailed analysis of species present in ambient air, and supplements continuous monitoring which reports a total concentration in real-time. Time-integrated monitoring methods consist of collecting ambient air samples using various media for a period of time, and then the media is sent to a laboratory for analysis. The WBEA's time-integrated data is searchable and historical laboratory results are available to everyone.
View Time-Integrated DataPollutants Monitored
The WBEA monitors numerous parameters, including pollutants of concern, through continuous and time-integrated monitoring methods to better understand the air quality in the Regional Municipality of Wood Buffalo (RMWB). Descriptions for these parameters are included in the table below, and the summary of pollutants monitored at each site can be found here.
All ambient air monitoring stations also continuously measure temperature, relative humidity, and wind speed and direction, and selected stations measure barometric pressure, global radiation, and surface wetness.
Collection Method: Continuous Monitoring | Time-Integrated Monitoring
NH3 is a natural compound found in the environment as part of the nitrogen cycle and can also come from human activity. NH3 is monitored by the WBEA because it is used by one industry member to help reduce SO2 emissions. Exposure to elevated concentrations of ammonia can cause irritation of the nose, throat, and respiratory tract. NH3 is currently monitored at the Bertha Ganter-Fort McKay and Patricia McInnes air monitoring stations.
Collection Method: Continuous Monitoring | Time-Integrated Monitoring
Elemental Carbon (EC), or “Black Carbon”, is the product of incomplete combustion of fuels which is mainly present in the ultrafine fraction of particulate matter (PM0.1). EC is a major component of diesel soot, which has been declared as a substance that can cause cancer by the World Health Organization (WHO, 2012). Organic Carbon (OC) is carbon bound in organic compounds which are directly emitted into the air, but also formed from organic precursor gases emitted from anthropogenic and natural sources (the latter relating primarily to terrestrial vegetation). Particles containing OC may also pose a significant risk to human health (Mauderly and Chow, 2008).
Collection Method: Continuous Monitoring
CO2 is a natural component of the air we breath. It is a colorless, odourless gas produced by respiration of plants and animals, and through combustion of fossil fuels. Ambient carbon dioxide is generally not a human health concern and is monitored in the network to help differentiate between origins of emissions such as forest fires and anthropogenic sources.
Collection Method: Continuous Monitoring
CO is formed from the incomplete combustion of carbon in fossil fuels. Transportation and vehicle emissions are the major source of carbon monoxide with elevated concentrations during the morning and evening rush hours. Breathing carbon monoxide decreases the amount of oxygen carried by the blood stream.
Collection Method: Time-Integrated Monitoring
Wet deposition samples are collected using ion exchange resins (IERs) as part of the WBEA’s Forest Health Monitoring (FHM) Program to measure nutrient deposition and to estimate atmospheric deposition inputs to forest ecosystems. Each sample is analyzed for major ions. The program focuses on sulphur and nitrogen ions, including nitrogen as ammonium (NH4-N), nitrogen as nitrate (NO3-N), and sulphur as sulphate (SO4-S), as well as base cations including, calcium (Ca), potassium (K), magnesium (Mg), sodium (Na), and phosphorous (P).
Collection Method: Continuous Monitoring
Methane (CH4) is the most abundant hydrocarbon on earth, while reactive non-methane hydrocarbons (NMHCs) can react with other compounds in atmosphere to form ozone. Total hydrocarbons (THC) are the combined concentrations on both methane and non-methane hydrocarbons. Some stations in the WBEA network only measure THCs, while certain stations measure CH4, NMHC, and THC. Many hydrocarbons are emitted from natural sources, while others can come from industrial and vehicular emissions. The natural background level of THC, composed mainly of CH4, is generally around 1.8 ppm.
Collection Method: Time-Integrated Monitoring
NO2 reacts with the hydroxyl (OH) radical to form HNO3 which in turn deposits rapidly or reacts with ammonia to form fine particulate ammonium nitrate.
Collection Method: Continuous Monitoring | Time-Integrated Monitoring
NO2 is a reddish-brown gas with a pungent, irritating odour that is produced by combustion of fossil fuels. It plays a major role in atmospheric photo-chemical reactions, ground level ozone formation and destruction, and can also interact with water to form acid rain.
Collection Method: Continuous Monitoring
NOx are poisonous gases derived from nitrogen and oxygen combustion under high pressure and temperatures. NOx is composed of nitric oxide (NO), and a smaller percentage of more poisonous nitrogen dioxide (NO2). There are other compounds in the family of oxides of nitrogen but typically only in trace amounts. NO and NO2 are generally considered to make up NOx.
Collection Method: Continuous Monitoring | Time-Integrated Monitoring
O3 at ground-level is not emitted directly into the air but formed by chemical reactions of NOx and volatile organic compounds (VOCs), from vehicular and industrial emissions. At high concentrations, breathing ozone can affect respiratory function, and cause coughing, throat irritation, and airway inflammation. Children, the elderly, and people with asthma are the most susceptible. Ozone can affect sensitive vegetation, by slowing plant growth and making them more susceptible to disease.
Collection Method: Continuous Monitoring | Time-Integrated Monitoring
Particulate matter consists of a mixture of solid particles and aerosols found in the air. PM<sub>10</sub> is the fraction of total particulate that are 10 µm (microns) in diameter or less.
The continuous analyzer measures the concentration of particulate matter in the air at any given time. A time-integrated PM10 sample is a measure of dry deposition and is analyzed for major ions similar to the wet deposition samples, and metals that make up the particulate matter in the air.
Collection Method: Continuous Monitoring | Time-Integrated Monitoring
Particulate matter consists of a mixture of solid particles and aerosols found in the air. PM 2.5 is the fraction of total particulate that are 2.5 µm (microns) in diameter or less, and is produced mainly by combustion processes, including forest fires.
Typically, exceedances of the PM2.5 AAAQO in the WBEA network are a result of forest fires. Fine particles are composed primarily of sulphate, nitrate, ammonium, inorganic and organic carbon compounds, and heavy metals. PM 2.5 poses a health risk as the particles can be inhaled deep into the lungs.
The continuous analyzer measures the concentration of particulate matter in the air at any given time. A time-integrated PM 2.5 sample is a measure of dry deposition and is analyzed for major ions similar to the wet deposition samples, and metals that make up the particulate matter in the air.
Collection Method: Time-Integrated Monitoring
PAHs are a type of hydrocarbon – an organic compound containing carbon and hydrogen – that are produced from natural sources, such as the incomplete combustion of organic matter, and can be found in oil sand deposits. There are more than 100 different PAHs – some of which can be detrimental to human health and the environment.
In the WBEA’s time-integrated sampling program, PAHs are collected on a sample media for a 24-hour period, every six days. These samples are collected and sent to the lab where they are analyzed to determine what PAHs were present in the air.
Collection Method: Continuous Monitoring | Time-Integrated Monitoring
SO2 is produced from the combustion of sulphur-containing fossil fuels. Sulphur dioxide in the air at high concentrations can make breathing difficult, particularly for children, the elderly, and people with asthma. SO2 reacts in the atmosphere to form sulphuric acid and acidic aerosols, which contribute to acid deposition and acid rain.
Collection Method: Continuous Monitoring
H2S is a colourless gas with a rotten egg odour. It is produced through industrial processes. The term “Total Reduced Sulphurs” covers a larger group of sulphur-containing compounds, including H2S, carbonyl sulphide, mercaptans, etc. These substances have the potential to cause odours in the region. In the WBEA airshed most industrial TRS and H2S emissions are from upgraders and tailings ponds, though there is a natural background ambient air concentration of the reduced sulphur compound carbonyl sulphide of approximately 0.5 ppb.
Collection Method: Time-Integrated Monitoring
VOCs are a group of chemical species that contain carbon, and react easily to become a gas. They may contain additional elements such as hydrogen, oxygen, fluorine, chlorine, bromine, sulphur, or nitrogen. VOCs are numerous, and come from both natural and human sources, and certain VOCs may contribute to ozone formation, odours, and long term health-effects.
In the WBEA’s time-integrated sampling program, an air sample is collected in a stainless-steel canister for a 24-hour period, every six days. These samples are then sent to the lab where they are analyzed to determine what VOCs were present in the air.