Isolating the effects of climate change in the variation of secondary inorganic aerosols (SIA) in Europe for the 21st century (1991–2100)

The analysis of the influence of future climatic variations on air quality needs of methods that give a space-time display of large atmospheric data related to air pollution. Here a new approach in order to assess the impacts of climate change on the patterns of variation of secondary inorganic aero...

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Bibliographic Details
Published in:Atmospheric environment (1994) 2011-02, Vol.45 (4), p.1059-1063
Main Authors: Jimenez-Guerrero, Pedro, Jose Gomez-Navarro, Juan, Jerez, Sonia, Lorente-Plazas, Raquel, Garcia-Valero, Juan Andres, Montavez, Juan Pedro
Format: Article
Language:English
Subjects:
Aerosols
air pollution
air quality
Air quality–climate interactions
ammonium nitrate
atmospheric chemistry
Atmospherics
Climate
Climate change
Climate modelling
Future air quality
gases
meteorological parameters
Methodology
mixing
Orthogonal functions
oxidants
Precipitation
Regional climate
sulfates
temperature
time series analysis
Trends
uncertainty
variance
wet deposition
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Summary:The analysis of the influence of future climatic variations on air quality needs of methods that give a space-time display of large atmospheric data related to air pollution. Here a new approach in order to assess the impacts of climate change on the patterns of variation of secondary inorganic aerosols (SIA) over Europe is presented. The most widely used method of analysis (selected time-slices, future-minus-present method) is very sensitive to the chosen control and future periods because of the internal variability of the climate system. In order to overcome this limitation, full transient simulations for the period 1991–2100 under the SRES A2 scenario are analysed by the Empirical Orthogonal Functions (EOFs) methodology in order minimise the uncertainty associated to the internal variability due to the longer time series obtained. The results indicate that the EOF1 accounts for around 30–45% of the total variance for the SIA levels and points out a general increase of its trend over the entire domain ( p < 0.005), except in the case of nitrate, whose change signal is not significant ( p > 0.1). The correlation between SIA and meteorological parameters indicates that the trends and patterns of variation of aerosols are related to the higher temperature projected for the future climate. It favours the formation of sulphates and ammonium (increasing the concentrations of atmospheric oxidants) and the decomposition of ammonium nitrate, remaining in the gas phase. Further, the decreases in precipitation have a strong effect on the frequency of the washout and therefore in the levels of aerosols. The concentrations of aerosols decrease with increasing precipitation as wet deposition provides the main aerosol sink. The trend from a decreasing mixing height found in several areas of Europe is frequently related to a decrease in precipitation, representing an adding effect for the enhanced future SIA concentrations. ► The spatio-temporal patterns of variability for secondary inorganic aerosols (SIA) under a changing climate are determined. ► Full transient simulations for the period 1991–2100 (SRES A2) are analysed by the Empirical Orthogonal Functions (EOFs) methodology. ► The EOFs analysis allows filtering the change signal of SIA and to identify their patterns of variability. ► Climatic change will impact air quality by increasing the mean concentrations of these aerosol components matter in most regions over Europe.
ISSN:1352-2310
1873-2844
DOI:10.1016/j.atmosenv.2010.11.022