Abstract
Ultrafine particles (UFP) are suspected of having significant impacts on health. However, there have only been a limited number of studies on sources of UFP compared to larger particles. In this work, we identified and quantified the sources and processes contributing to particle number size distributions (PNSD) using Positive Matrix Factorization (PMF) at six monitoring stations (four urban background and two street canyon) from four European cities: Barcelona, Helsinki, London, and Zurich. These cities are characterised by different meteorological conditions and emissions. The common sources across all stations were Photonucleation, traffic emissions (3 sources, from fresh to aged emissions: Traffic nucleation, Fresh traffic – mode diameter between 13 and 37 nm, and Urban – mode diameter between 44 and 81 nm, mainly traffic but influenced by other sources in some cities), and Secondary particles. The Photonucleation factor was only directly identified by PMF for Barcelona, while an additional split of the Nucleation factor (into Photonucleation and Traffic nucleation) by using NOx concentrations as a proxy for traffic emissions was performed for all other stations. The sum of all traffic sources resulted in a maximum relative contributions ranging from 71 to 94% (annual average) thereby being the main contributor at all stations. In London and Zurich, the relative contribution of the sources did not vary significantly between seasons. In contrast, the high levels of solar radiation in Barcelona led to an important contribution of Photonucleation particles (ranging from 14% during the winter period to 35% during summer). Biogenic emissions were a source identified only in Helsinki (both in the urban background and street canyon stations), that contributed importantly during summer (23% in urban background). Airport emissions contributed to Nucleation particles at urban background sites, as the highest concentrations of this source took place when the wind was blowing from the airport direction in all cities.
Highlights
It has been widely reported that atmospheric particulate matter (PM) has a negative impact upon human health, with 7 million deaths per year attributed to the exposure to air pollution (WHO, 2018)
We identified and quantified the sources and processes contributing to particle number size distributions (PNSD) using Positive Matrix Factorization (PMF) at six monitoring stations from four European cities: Barcelona, Helsinki, London, and Zurich
The Photonucleation factor was only directly identified by PMF for Barcelona, while an additional split of the Nucleation factor by using NOx concentrations as a proxy for traffic emissions was performed for all other stations
Summary
It has been widely reported that atmospheric particulate matter (PM) has a negative impact upon human health, with 7 million deaths per year attributed to the exposure to air pollution (WHO, 2018). Condensation or nucleation, depends on the availability of pre-existing particle surface area (condensation sink; McMurry and Friedlander, 1979) along with the dilution and cooling rate (Morawska et al, 2008) Those nucleated particles have been named delayed primary aerosols by Rönkkö et al (2017) since they are typically present in the particle phase in normal ambient air temperatures. Secondary particles are generated from gaseous precursors from vehicle exhaust emissions when fully diluted within the ambient air and, driven by photochemistry, are oxidised by reactive species This oxidation causes VOCs to turn into less volatile species, enhancing secondary aerosol formation by condensation and new particle formation (Gentner et al, 2012; Robinson et al, 2007; Volkamer et al, 2006)
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