engleski

Urban air pollution in the global hotspot of the Western Balkans region: lessons learned from the Sarajevo Canton Winter Field Campaign 2018 (SAFICA)

Atmospheric aerosols have well documented detrimental effects on human health, ecosystems and air quality and are the key uncertainty in assessing the anthropogenic influence on climate change. Particularly during the cold weather season, urban centers in countries of the Western Balkans region such as Bosnia and Herzegovina (BiH) are experiencing some of the globally poorest air quality due to the extensive use of solid fuels and old vehicle fleet. The city of Sarajevo is the capital of BiH and is situated in Southeastern Europe within a plain surrounded by mountains. In the winter months (domestic heating season), topography and meteorology cause the pollutants to be trapped within the city plain. Recent analysis with the US EPA BenMAP model applied to BiH found that an annual decrease of 50% in fine aerosol would save 4760+ lives and costs of $2.3B annually (Žero et al., 2022). Countries of the Western Balkans lack state‐of‐ the‐ art atmospheric sciences research despite high levels of ambient pollution and position within the EU borders, which makes it imperative to understand the emission sources, processing and the adverse health effects of their atmospheric aerosol pollution. This presentation will highlight the results of the SAFICA 2018 project, the first Sarajevo, BiH project aiming to yield crucial, not previously available information about aerosol emission sources and atmospheric transformations through combination of online field (black carbon and particle number and size distribution) and offline laboratory (physicochemical characterization of daily PM10 filter samples) measurements. Laboratory analyses of PM10 samples determined aerosols’ bulk chemical composition, selected elements (Huremović et al., 2020 ; Žero et al., 2022) and molecular species (Pehnec et al., 2020). Aerosol chemical composition determined by aerosol mass spectrometry was further analyzed by Positive Matrix Factorization to separate organic aerosol (OA) into subtypes characteristic for their sources and atmospheric processes. Aerosol oxidative potential (OP) was also determined to evaluate the ability of SAFICA aerosols to generate reactive oxygen species. Main SAFICA results show that ~3/4 of aerosol mass is carbonaceous (OA + black carbon) and ~2/3 of total carbon (TC) mass is from non‐fossil sources (Figure 1). Aerosol has high loadings of black carbon and toxic species, indicating strong and diverse combustion sources and likely a major public health danger. More work is needed to estimate the contributions of different aerosol sources and species to total aerosol OP. Finally, this presentation will show how SAFICA knowledge gaps will be overcome in a future project, planned to take place during 2022‐2023, entitled Sarajevo Aerosol Experiment: Composition, Sources and Health Effects of Atmospheric Aerosol (SAAERO). We thank Federal Hydrometeorological Institute of BiH, Magee Scientific/Aerosol and TSI for support. We acknowledge the contribution of the COST Action CA16109 COLOSSAL and SEE Change Net. KDž and ASHP acknowledge the grant by the Swiss NSF (Scientific Exchanges IZSEZ0_189495), KDž, GM and ASHP European Commission funding of SAAERO project (EU H2020 MSCA-IF 2020 grant # 101028909), GM the Slovenian Science foundation program P1-0385, and SF by the Croatian Science Foundation (BiREADI IP- 2018-01-3105).

Sarajevo ; SAFICA ; Urban air pollution ; PM10 ; source apportionment

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