Grange S. K., Fischer A., Zellweger C., Alastuey A., Querol X., Jaffrezo J. L., Weber S., Uzu Gaëlle, Hueglin C. (2021). Switzerland's PM10 and PM2.5 environmental increments show the importance of non-exhaust emissions. Atmospheric Environment-X, 12, p. 100145 [14 p.].
Titre du document
Switzerland's PM10 and PM2.5 environmental increments show the importance of non-exhaust emissions
Année de publication
2021
Auteurs
Grange S. K., Fischer A., Zellweger C., Alastuey A., Querol X., Jaffrezo J. L., Weber S., Uzu Gaëlle, Hueglin C.
Source
Atmospheric Environment-X, 2021,
12, p. 100145 [14 p.]
Atmospheric particulate matter (PM) is a priority pollutant for urban air pollution management because of its negative effects on human health and visibility. Emissions from road traffic have been a major focus of management over the past few decades, but non-exhaust emissions i.e., emissions from brake, tyre, road wear, and the resuspension of dust have emerged to become a major source of unregulated PM in many locations. Here, a filter-based sampling campaign was conducted between 2018 and 2019 where a large number of PM constituents were quantified for five sites in Switzerland for both PM10 and PM2.5. This had the objective of investigating urban and urban-traffic PM increments in Switzerland. The results show that PM concentrations increased as the sampling locations moved along a rural to urban-traffic gradient. However, source apportionment analysis showed that sulfate-rich, nitrate-rich, and biogenic sources were not enhanced in urban environments, but road traffic and mineral dust sources were. The total mass enhancement for PM10 and PM 2.5 were 2.4 mu g m(-3) and 2.0 mu g m(-3) for the urban environment while the corresponding urban-traffic enhancements were 5.7 mu g m(-3) and 2.8 mu g m(-3). Emissions from road traffic were estimated to contribute more than 75% to the urban increments and non-exhaust emissions contributed 48% (PM10) and 25% (PM2.5) to the total road traffic related increment at an urban background site and 62% (PM10) and 49% (PM2.5) at an urban-traffic site. Analysis of the composition of Switzerland's PM showed that elements associated with non-exhaust emissions, specifically the brake wear tracers of antimony, barium, copper, and iron were the metals with the greatest urban and urban-traffic enhancements. Critically, the urban increment of these elements was enhanced for both PM10 and PM2.5 by about the same magnitude as the urban-traffic increment (by 2-3 times), demonstrating non-exhaust emissions are encountered across urban areas, not just the urban-traffic environment. Therefore, non-exhaust emissions were an important contributor to the urban and urban-traffic PM10 and PM2.5 increments in Switzerland's urban areas. The relative contributions of non-exhaust emissions to the urban and urban-traffic increments could be expected to increase due to the introduction of further exhaust after-treatment technologies (such as gasoline particulate filters; GPFs) and the transition to a more electrified vehicle fleet. A management pivot will be required to control these non-exhaust emission pathways and although this work exclusively uses data from Switzerland, the conclusions are likely relevant to many other European urban areas.
Plan de classement
Sciences du milieu [021]
;
Pollution [038]
;
Urbanisation et sociétés urbaines [102]
Description Géographique
SUISSE ; EUROPE
Localisation
Fonds IRD [F B010083801]
Identifiant IRD
fdi:010083801
