PM10

Sources of Particulate Matter <10µm (PM10)

Particulate matter's physical composition is ambiguous, ranging from both solid and aerosol particles suspended in air. It is comprised of a mixture of dust, minerals, carbon molecules, sulphates, heavy metals, and water. Particulate matter ≤10 micrometres (µm) in diameter but ≥ 2.5 µm, and are classified as 'coarse particles' called PM10. For scale, a human hair has a diameter of ~70 µm. 

PM10s can come from a variety of anthropogenic sources. In the home, PM10s can originate from burning fuels for heating or cooking. Farms can release particles into the air via tilling of soil and through animal movement. Factories and vehicles which burn fossil fuels release lots of particulate matter, and even brakes, tyres, and unpaved roads can emit PM10s. Dust can contribute greatly to PM10 levels -- much more so than PM2.5 levels -- so a dusty household or a construction/demolition site can both experience heightened PM10 concentrations. Natural sources of PM10 include wildfires, pollen, sea spray and volcanic eruptions. 

Some sources of PM are defined as 'primary particles', meaning they are emitted into the air directly from a source (e.g., dust, smoke). Secondary particles are formed within an environment through chemical reactions (e.g., ammonia reacts with nitrogen oxides to form ammonium nitrate). Levels of PM10 exposure are dependent on the type of built environment you live in (e.g., an area close to a motorway or a factory might see higher PM10 levels). Lifestyle choices can also affect PM10 exposure, like burning log fires or cleaning the house regularly. Unfortunately, socio-economic status can have a significant influence on PM10 exposure, particularly by restricting where people in lower socio-economic groups can live and work.

Typical Sources of PM10

• Combustion Fumes Related to Transport & Industry
• Abrasion of Breaks, Tyres and Road Surface
• Construction, Mining, Demolition and Agricultural Dust
• Wildfires, Pollen, Seaspray and Volcanic Eruptions

Impacts of Indoor PM10

Particulate matter is both a carcinogen and a respiratory and cardiovascular irritant, causing both short-term and long-term health effects. PM10, due to its size, is more likely to deposit in the upper region of the lung, and generally irritates the ENT systems. While PM2.5 is more capable of penetrating deep into the respiratory and circulatory systems and causing damage, PM10 can worsen pre-existing respiratory diseases. The severity of this effect is heightened in vulnerable groups like children and the elderly.

Common Impacts of PM10

• Irritation of the ENT Systems
• The development and worsening of Cardiovascular and Respiratory Disease
• Reduction in Life Expectancy
• Negatively Impact Cognitive Functions

Testing for PM10

Testing for PM10 is relatively easy to carry out. With the use of the Temptop M2000, we can perform point-in-time readings of PM10 in a given environment. It uses a Laser PM Sensor to detect PM10 to a resolution of 0.1µg/m³. Many domestic air quality monitors also include PM10 as a measurable pollutant.

• Temptop M2000 2nd
• Air Quality Monitors
  

 

Limits of PM10 (normally in µg/m³ )  are variable within legislation depending on the environmental type and activities performed in said environment.  The Air Quality Standards Regulations (2010) set an annual average for outdoor PM10 levels at 40 µg/m3. The WHO's recommended annual average concentration of PM10 is 15 μg/m3. It is stated that there is no safe amount of PM to have within the air, so all efforts to reduce PM should be maximised to ALARP.

• The Air Quality Standards Regulations (2010) limit is ≤40 µg/m3
• DEFRA defines high levels of PM10 at 76-83 µg/m³
• The World Health Organisation (WHO) recommend < 15 μg/m3