Abstract
The surface area of ambient aerosols can be considered as an index of toxicity because an increased surface area may be able to act as a catalyst for specific reactions between particles and cells, as well as a carrier for co-pollutants, such as gases and chemicals. The aerosol surface area concentration was measured together with black carbon (BC) and other chemical species such as organic compounds, sulfate, and nitrate in Fukuoka, Japan, and the effect of the chemical composition of aerosols on their surface area was investigated. Aerosol surface area concentration was highly correlated with BC concentration for the entire period. Day-of-week variation and diurnal variation also showed the strong correlation between aerosol surface area and BC. This implies that even though BC accounts for relatively small percentage (in this study, 3.5%) of PM2.5 mass, it should receive considerable attention when aerosol surface area is considered as an index of adverse health effects caused by exposure of the human body to aerosols. Sulfate aerosol does not usually affect aerosol surface area in Fukuoka, but it may occasionally have a significant effect when the airmass contains an excess amount of relatively smaller particles of sulfate derived from volcanic SO2.
Highlights
IntroductionA large number of studies are currently being conducted, or are planned for the future, that are directed toward understanding the effects of exposure to atmospheric aerosols on human health
A large number of studies are currently being conducted, or are planned for the future, that are directed toward understanding the effects of exposure to atmospheric aerosols on human health.This is based on the worldwide acknowledgement that these aerosols are potentially hazardous to humans [1,2,3]
Aerosol Surface Area is Generally Controlled by Black Carbon
Summary
A large number of studies are currently being conducted, or are planned for the future, that are directed toward understanding the effects of exposure to atmospheric aerosols on human health. This is based on the worldwide acknowledgement that these aerosols are potentially hazardous to humans [1,2,3]. Numerous researchers conducting particle exposure experiments on rats or mice have proposed that surface area is a more appropriate indicator than mass for evaluating pulmonary inflammatory responses caused by exposure to manufactured nanomaterials, such as TiO2 , fullerenes, and carbon nanotubes [8,9,10].
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