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Wildfire particulate matter as a source of environmentally persistent free radicals and reactive oxygen species

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ENVIRONMENTAL SCIENCE-ATMOSPHERES
卷 3, 期 3, 页码 581-594

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ROYAL SOC CHEMISTRY
DOI: 10.1039/d2ea00170e

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Wildfires in the era of climate change emit substantial amounts of particulate matter into the atmosphere, which significantly impacts air quality and public health. However, there is a lack of data on the specific components of these particulate matter that are associated with wildfires, hindering our understanding of their effects on climate and human health.
Wildfires, which have been occurring increasingly in the era of climate change, emit massive amounts of particulate matter (PM) into the atmosphere, strongly affecting air quality and public health. Biomass burning aerosols may contain environmentally persistent free radicals (EPFRs, such as semiquinone radicals) and redox-active compounds that can generate reactive oxygen species (ROS, including center dot OH, superoxide and organic radicals) in the aqueous phase. However, there is a lack of data on EPFRs and ROS associated with size-segregated wildfire PM, which limits our understanding of their climate and health impacts. We collected size-segregated ambient PM in Southern California during two wildfire events to measure EPFRs and ROS using electron paramagnetic resonance spectroscopy. EPFRs are likely associated with soot particles as they are predominantly observed in submicron particles (PM1, aerodynamic diameter <= 1 mu m). Upon extraction in water, wildfire PM mainly generates center dot OH (28-49%) and carbon-centered radicals (similar to 50%) with minor contributions from superoxide and oxygen-centered organic radicals (2-15%). Oxidative potential measured with the dithiothreitol assay (OP-DTT) is found to be high in wildfire PM1, exhibiting little correlation with the radical forms of ROS (r(2) <= 0.02). These results are in stark contrast with PM collected at highway and urban sites, which generates predominantly center dot OH (84-88%) that correlates well with OP-DTT (r(2) similar to 0.6). We also found that PM generated by flaming combustion generates more radicals with higher OP-DTT compared to those by smoldering or pyrolysis.

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