Air stagnation in Europe: Spatiotemporal variability and impact on air quality

•First characterization of the spatiotemporal variability of air stagnation in Europe•Fair agreement between stagnation as derived from reanalysis and observations•Large spatial heterogeneity, with more stagnation in southern and central Europe•O3 and PM10 increase by 14–23% and 45–58% on stagnant d...

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Bibliographic Details
Published in:The Science of the total environment 2018-12, Vol.645, p.1238-1252
Main Authors: Garrido-Perez, Jose M., Ordóñez, Carlos, García-Herrera, Ricardo, Barriopedro, David
Format: Article
Language:English
Subjects:
Air pollution
Air stagnation
Meteorology
Ozone
Particulate matter
Regional air quality
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Summary:•First characterization of the spatiotemporal variability of air stagnation in Europe•Fair agreement between stagnation as derived from reanalysis and observations•Large spatial heterogeneity, with more stagnation in southern and central Europe•O3 and PM10 increase by 14–23% and 45–58% on stagnant days in 3 out of 5 regions.•Strong build-up of O3 and PM10 over most regions during widespread stagnant episodes [Display omitted] This paper characterizes the spatiotemporal variability of air stagnation over the Euro-Mediterranean area for the 1979–2016 period by using a simplified air stagnation index (ASI) based on daily precipitation as well as near-surface and upper wind speed data. We have also undertaken the first comparison of stagnation as derived from meteorological reanalysis and observations, finding a reasonably good agreement between both datasets. The main differences arise from the surface wind speed, as this field depends on the local setting of the observational sites and imperfect parameterizations within the reanalysis model. Since air stagnation has considerable spatial heterogeneity over the region, we have regionalized the monthly frequency of stagnant days, resulting five regions with consistent temporal patterns: Scandinavia (SCAN), Northern-Europe (NEU), Central-Europe (CEU), South-West (SW) and South-East (SE). The northern regions (SCAN and NEU), which are affected by moderately strong near-surface winds and ample precipitation, present low frequency and temporal variability in stagnation compared to the southern regions (SW and SE). The winters and summers with the highest stagnation frequency often concur with positive 500 hPa geopotential height anomalies over the regions, with the exception of negative anomalies and a displacement of the extratropical jet to the south in the case of SCAN and NEU during winter. Air stagnation exerts a clear influence on air quality (AQ), with anomalies above 10% for summer ozone (O3) and 30% for winter PM10 (particulate matter ≤10 μm in diameter) on stagnant vs. non-stagnant days over most of the regions. These values exceed 20% and 50%, respectively, in the case of CEU, where air stagnation also drives significant changes in the frequency distributions of these pollutants and increases the likelihood of AQ exceedances. Moreover, persistent and widespread stagnation events favour the build-up of both O3 and PM10 over most of the continent.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2018.07.238