Relative Contribution of Outdoor and Indoor Particle Sources to Indoor

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Environ. Sci. Technol. 2000, 34, 3579-3587

Relative Contribution of Outdoor and Indoor Particle Sources to Indoor Concentrations E I L E E N A B T , * ,† H E L E N H . S U H , ‡ PAUL CATALANO,§ AND PETROS KOUTRAKIS‡ Board on Environmental Studies and Toxicology, National Research Council/National Academy of Science, 2101 Constitution Avenue, HA354, Washington, D.C. 20418, Department of Environmental Health and Department of Biostatistics, School of Public Health, Harvard University, 665 Huntington Avenue, Boston, Massachusetts 02115

The effect of indoor particle sources on indoor particle size distributions and concentrations was previously investigated using real-time indoor and outdoor particle size distribution data collected in four homes in Boston in 1996. These data demonstrated the importance of indoor sources (i.e., cooking, cleaning, and movement of people) and air exchange rates on observed indoor concentrations. As part of the continued analyses of these data, a simple physical model was used to determine the source emission and infiltration rates for specific particle sizes. Decay rates were also estimated. Cooking, cleaning, and indoor work (characterized by movement of people) significantly increased PM(0.7-10) concentrations by 0.27, 0.27, and 0.25 µm3 cm-3 min-1, respectively. Cooking was the only variable significantly associated with generation of particles less than 0.5 µm in diameter. Outdoor particles (0.02-0.5 and 0.7-10 µm) were found to contribute significantly to indoor particle levels. Effective penetration efficiencies ranged from 0.38 to 0.94 for 0.02-0.5 µm particles and from 0.12 to 0.53 for 0.7-10 µm particles. Estimates for 0.7-10 µm particles decreased with increasing particle size, reflecting the influence of deposition losses from gravitational settling. The real-time particle size distribution data in conjunction with time-activity information provides valuable information on the origin and fate of indoor particles.

Introduction Despite the expanding database of information on exposures to particles, little is known about the temporal variability and size distribution of indoor particulate exposures. Several factors contribute to this lack of information. Aerosol sampling technology for exposure assessment purposes has focused primarily on integrated measurement techniques, which typically measure only particle mass. Only recently have particle size measurement methods (e.g., laser particle counters, electrical mobility analyzers, piezo balances) been implemented for use in measuring indoor and outdoor particle size distributions in homes (1-6). Estimation of * Correspondening author phone: (202)334-2756; fax: (202)3342752; e-mail: [email protected]. † National Research Council/National Academy of Science. ‡ Harvard University, Department of Environmental Health. § Harvard University, Department of Biostatistics. 10.1021/es990348y CCC: $19.00 Published on Web 08/02/2000

 2000 American Chemical Society

parameters affecting indoor exposures including source emission rates, deposition velocities, and penetration efficiencies is very difficult because of the myriad of factors influencing these parameters, such as air exchange rates, windspeed, indoor and outdoor temperatures, and housing structure. Previous studies gathered information on indoor sources of particles (1-4, 7-9) and measured the size distribution of the emitted particles. These studies provide corroborating evidence that the major source of fine particles (