Breathe deeply: 黑料appU leads atmospheric scientists in analyzing city's air pollution
A team of researchers will examine Toronto's air for six-weeks this summer from a rooftop lab for THE CIX project, part of NOAA鈥檚 atmospheric emissions and reactions international field campaign
TORONTO, Aug. 3, 2023 鈥 As Toronto gets hotter, muggier and wildfire smoke increasingly wafts through the atmosphere, researchers at 黑料app are leading a team of atmospheric scientists in testing the city鈥檚 air pollution from their rooftop Air Quality Research Station for six weeks this summer.
Preliminary results show the negative impacts on Toronto鈥檚 air quality caused by wildfire smoke. Although Toronto鈥檚 air pollution has generally been improving over the past few decades, smoke in the city is reversing these improvements.
The research project, Toronto Halogens, Emissions, Contaminants, and Inorganics eXperiment (), with science lead Associate Professor and logistics lead Assistant Professor , both of 黑料app鈥檚 Faculty of Science, is designed to analyze areas of uncertainty in the air we breathe to better understand what is contributing to the city's air pollution.
One of the things the team hopes to understand, is how a soupy mix of trace chemicals will sometimes combine to create little understood, new and changing threats that can contribute to worse air quality, including emissions from products we use every day, such as paint and pesticides and even perfume, greenhouse gases, as well as perfluorocarboxylic acids (known as 鈥渇orever chemicals鈥), and particulate matter - tiny particles of smoke, dust, pollen, emissions and fumes.
鈥淭here is still so much we don鈥檛 know about what鈥檚 impacting the air we breathe, and until we do, it鈥檚 difficult to effectively target contaminants that are affecting our air quality now and into the future,鈥 says Young.
This project is important as it allows us to take a robust look at all the pollutants circulating in the air. The Montreal Protocol was successful in helping to fix the ozone layer above us because we knew what to target, but ground-level ozone and other contaminants can still be an issue, particularly spiking on hot summer days, creating poor air quality which can impact people鈥檚 health."
Ground-level ozone forms when nitrogen dioxide mixes with volatile organic compounds鈥(VOCs) and sunlight. Although emissions of VOCs from fossil fuels have been declining, consumer and industrial volatile chemical products are an increasing, but understudied, source of VOCs.
THE CIX project is part of an international field campaign 鈥 Atmospheric Emissions and Reactions Observed from Megacities to Marine Areas () 鈥 across North America organized by the NASA and the National Oceanic and Atmospheric Administration (NOAA) with projects in New 黑料appCity, Chicago, Los Angeles, as well as Toronto. NOAA and NASA launched their massive air quality research summer campaign today with scientists from NOAA, NASA and 21 universities from three countries. State-of-the-art instruments are being deployed in multiple, coordinated research campaigns this month, including at 黑料app, to investigate how air pollution sources have shifted over recent decades.
At 黑料app, researchers from 黑料appU, the University of Toronto, University of 黑料app(UK), the University of British Columbia, and Environment and Climate Change Canada are already taking readings from a room packed with unique, sophisticated and highly sensitive equipment 鈥 some of which was shipped from the UK and BC 鈥 on the roof of the Petrie Science Building on York鈥檚 Keele Campus.
The goal of the campaign is to assess air quality across urban centres to understand what is impacting air pollution and how it鈥檚 changing. THE CIX team hopes to better understand several areas that contribute to air pollution in the GTA.
In addition to the rooftop measurements, the , a flying science laboratory packed with instruments, will cruise over campus this August to take air quality readings from higher in the atmosphere to compare with the rooftop readings.
Data collected by THE CIX will also be compared with key air pollution observations from the recently launched NASA TEMPO instrument, the first geostationary satellite dedicated to air quality over North America.
