Use of Time- and Chemically Resolved Particulate Data To Characterize the Infiltration of Outdoor PM sub(2.5) into a Residence in the San Joaquin Valley

Use of Time- and Chemically Resolved Particulate Data To Characterize the Infiltration of Outdoor PM sub(2.5) into a Residence in the San Joaquin Valley

Recent studies associate particulate air pollution with adverse health effects. The indoor exposure to particles of outdoor origin is not well-characterized, particularly for individual chemical species. In response to this, a field study in an unoccupied, single-story residence in Clovis, CA, was c...

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Bibliographic Details
Published in:Environmental science & technology Vol. 37; no. 20; pp. 4724 - 4732
Main Authors: Lunden, M M, Thatcher, T L, Hering, S V, Brown, N J
Format: Journal Article
Language:English
Published: 15-10-2003
Subjects:
USA, California, Clovis
USA, California, San Joaquin Valley
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Summary:Recent studies associate particulate air pollution with adverse health effects. The indoor exposure to particles of outdoor origin is not well-characterized, particularly for individual chemical species. In response to this, a field study in an unoccupied, single-story residence in Clovis, CA, was conducted. Real-time particle monitors were used both outdoors and indoors to quantity PM sub(2.5) nitrate, sulfate, and carbon. The aggregate of the highly time-resolved sulfate data, as well as averages of these data, was fit using a time-averaged form of the infiltration equation, resulting in reasonable values for the penetration coefficient and deposition loss rate. In contrast, individual values of the indoor/outdoor ratio can vary significantly from that predicted by the model for time scales ranging from a few minutes to several hours. Measured indoor ammonium nitrate levels were typically significantly lower than expected solely on the basis of penetration and deposition losses. The additional reduction is due to the transformation of ammonium nitrate into ammonia and nitric acid gases indoors, which are subsequently lost by deposition and sorption to indoor surfaces. This result illustrates that exposure assessments based on total outdoor particle mass can obscure the actual causal relationships for indoor exposures to particles of outdoor origin.
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ISSN:0013-936X
DOI:10.1021/es026387i