High-resolution modelling of organic aerosol over Europe: exploring spatial and temporal variability and drivers
article
Banos, D.T.
Upadhyay, A.
Cheng, Y.
Jiang, J.
Vasilakos, P.
Nava, A.
Severa, P.
Fluechiger, B.
Bougiatioti, A.
Campa Verdona, A.M.S. De La
Schemmel, A.
Alastuey, A.
Vasanits, A.
Font, A.
Tobler, A.
Bourin, A.
Machon, A.
Chazeau, B.
Bergmans, B.
Alves, C.A.
Voiron, C.
Hueglin, C.
Lin, C.
Belis, C.A.
Colombi, C.
Reche, C.
Navarro, D.A.S.
Massabo, D.
Green, D.C.
Cuccia, E.
Freney, E.
Giardi, F.
Canonaco, F.
Uzu, G.
Chen, G.I.
Keernik, H.
Flentje, H.
Herrmann, H.
Chebaicheb, H.
Timonen, H.
Denier van der Gon, H.A.C.
Stavroulas, I.
Salma, I.
Schwarz, J.
Necki, J.
Sciare, J.
Petit, J.E.
Jaffrezo, J.L.
Vasilescu, J.
De La Rosa, J.D.
Pauraite, J.
Ovadnevaite, J.
Yttri, K.E.
Eleftheriadis, K.
Poulain, L.
Belegante, L.
Alados-Arboledas, L.
Manousakas, M.I.
Paglione, M.
Maasikmets, M.
Minguillon, M.C.
Gini, M.I.
Rinaldi, M.
Pikridas, M.
Aurela, M.
Merchand, N.
Zografou, O.
Favez, O.
Vodicka, P.
Pokorna, P.
Lhotka, R.
Atabaksh, S.
Conil, S.
Castillo, S.
Gilardoni, S.
Platt, S.M.
Grange, S.K.
Poluzzi, V.
Kumar, V.
Riffault, V.
Aas, W.
Querol, X.
Sosedova, Y.
Probst-Hensch, N.
Vienneau, D.
Prevot, A.S.H.
Hoogh, K. de
Daellenbach, K.R.
Krymova, E.
El Haddad, I.
Organic aerosol (OA) is a major component of atmospheric particulate matter (PM), affecting both human health and climate. However, high-resolution estimates of OA exposure needed for exposure analysis remain scarce. Here, we integrate a chemical transport model (CAMx) with a random forest (RF) machine learning approach to bias-correct and downscale daily OA concentrations across Europe. CAMx OA simulations at ~15 km resolution show moderate agreement with observations (r = 0.55). By combining these outputs with high-resolution land use data and training the RF model on ~48,000 daily OA measurements from 137 sites, prediction accuracy improved (r = 0.65), with ~l5% reduction in root mean square error. The resulting maps provide European daily OA concentrations at ~250 m resolution for alternate years from 2011 to 2019. The model captures key spatial features, including elevated OA in the Po Valley, Southeastern, and Central Europe, as well as intracity variations due to local hotspots. Seasonal analysis reveals higher concentrations in winter, while long-term trends indicate a general decline in OA levels. Exposure estimates show that half of the European population experiences OA levels above 3 µg/m3 , and ~50 million people are exposed to more than 5 µg/m3 , which is the current guideline level recommended by the world health organization for total PM2.5. These high-resolution OA maps offer vital critical support for epidemiological research and air quality policy
Topics
TNO Identifier
1025811
Source
Environment International(209), pp. 1-14.
Pages
1-14