Car Passengers Can Reduce Pollution Risk by Closing Windows and Changing Route
The University of Birmingham recently released a press release about how individuals can reduce their exposure to pollution with simple solutions such as closing windows or changing route.
The University of Birmingham recently released a press release about how individuals can reduce their exposure to pollution while driving to work, to the store or on any other outing.
Pollution is not just bad for the environment. Particulate matter in the air affects humans’ respiratory and physical health, and scientists say it can put people at higher risk of severe cases of COVID-19 by exacerbating respiratory systems. Pollution can also affect people’s lung heath and susceptibility to pulmonary disease.
While air pollution is a large contributor to the climate crisis and environmental strains, these issues have humanitarian affects. Workers, families, and individuals young and old should be aware of the pollution they are exposed to.
Below is the press release from the University of Birmingham about the ways that car passengers can reduce their exposure to particulate matter with simple solutions such as closing windows or changing route.
Car Passengers Can Reduce Pollution Risk by Closing Windows and Changing Route
Drivers and passengers can inhale significantly lower levels of air pollution by setting their vehicle’s ventilation systems more effectively and taking a ‘cleaner’ route to their destination, a new study reveals.
Road transport emissions are major source of urban air pollution - nitrogen oxides (NOx) and particulate matter (PM) coming from vehicle exhausts, plus non-exhaust emissions such as brake dust, tyre wear and road dust in the case of PM.
Outdoor air pollution is estimated to contribute to 40,000 deaths in Britain annually and an estimated 7 million deaths globally—linked to diseases ranging from lung cancer to stroke and respiratory infection.
Scientists at the University of Birmingham have found that—if vehicle ventilation is set correctly—drivers and passengers are exposed to up to 49 percent less P2.5 and 34 percent less Nitrogen Dioxide (NO2) than the on-road levels. They have published their findings in the journal Atmospheric Environment.
Lead author Dr. Vasileios Matthaios, from the University of Birmingham, commented: “Exposure to air pollution within the vehicle depends upon both the ventilation setting and the type of route. The lowest exposure to particles and gases is when the windows are closed with recirculation and air conditioning switched on.
“Drivers and passengers inhale more air pollution when traveling on urban roads, followed by ring-roads and sub-urban roads. However, because concentrations inside a vehicle are lower and occupants are not as active, they inhale less air pollution than people cycling or walking on the same routes.”
Researchers explored within-vehicle levels of NO2 and PM2.5 under different vehicle ventilation settings and driving routes during real-world driving experiments around the city of Birmingham.
Four vehicles were driven on a consistent route of three contrasting road types, measuring simultaneous within-vehicle and ambient levels of particulate matter (PM10, PM2.5, PM1), ultrafine particles number (UFP), lung surface deposited area (LSDA), nitric oxide (NO) and nitrogen dioxide (NO2).
“Our findings show that vehicle passengers can modify their exposure and inhalation dose through ventilation setting and route choice - this may have significant health impacts upon the most exposed groups such as professional drivers,” Dr. Vasileios Matthaios added.
Increasing urbanization together with growth in vehicle ownership and passenger-journeys have contributed to growth in traffic-related ambient air pollution.
Researchers noted that related health issues depend on an individual’s exposure to air pollution and the vulnerability of the individual to a given dose. This, in turn, depends on route selection, time of day, transport type, respiration rate and, in the case of vehicles, ventilation options and efficacy and type of cabin filters.
As part of the MMAP-VEX project ‘Measuring and Modelling Air Pollution Within Vehicles – Implications for daily EXposure and Human Health’, University of Birmingham researchers will further investigate other aspects that affect within vehicle air pollution under real world driving conditions, including:
- Testing different types of cabin filters such as activated carbon and standard pollen cabin filters, to find their infiltration efficacy;
- Influence of indoor air purifiers to within-vehicle exposure reduction; and
- Passenger exposure variation at different driving locations, for example waiting at traffic lights, roundabouts and in tunnels.