Influence of Ambient (outdoor) Sources on Residential Indoor and Personal PM2.5 Concentrations: Analyses of RIOPA Data

Overview

Journal J Expo Anal Environ Epidemiol

Specialties Environmental Health
Public Health

Date 2004 May 13

PMID 15138449

Citations 53

Authors

Qing Yu Meng

Barbara J Turpin

Leo Korn

Clifford P Weisel

Maria Morandi

Steven Colome

Junfeng Jim Zhang

Thomas Stock

Dalia Spektor

Arthur Winer

Lin Zhang

Jong Hoon Lee

Robert Giovanetti

William Cui

Jaymin Kwon

Shahnaz Alimokhtari

Derek Shendell

Jennifer Jones

Corice Farrar

Silvia Maberti

Affiliations

Soon will be listed here.

Abstract

The Relationship of Indoor, Outdoor and Personal Air (RIOPA) study was designed to investigate residential indoor, outdoor and personal exposures to several classes of air pollutants, including volatile organic compounds, carbonyls and fine particles (PM2.5). Samples were collected from summer, 1999 to spring, 2001 in Houston (TX), Los Angeles (CA) and Elizabeth (NJ). Indoor, outdoor and personal PM2.5 samples were collected at 212 nonsmoking residences, 162 of which were sampled twice. Some homes were chosen due to close proximity to ambient sources of one or more target analytes, while others were farther from sources. Median indoor, outdoor and personal PM2.5 mass concentrations for these three sites were 14.4, 15.5 and 31.4 microg/m3, respectively. The contributions of ambient (outdoor) and nonambient sources to indoor and personal concentrations were quantified using a single compartment box model with measured air exchange rate and a random component superposition (RCS) statistical model. The median contribution of ambient sources to indoor PM2.5 concentrations using the mass balance approach was estimated to be 56% for all study homes (63%, 52% and 33% for California, New Jersey and Texas study homes, respectively). Reasonable variations in model assumptions alter median ambient contributions by less than 20%. The mean of the distribution of ambient contributions across study homes agreed well for the mass balance and RCS models, but the distribution was somewhat broader when calculated using the mass balance model with measured air exchange rates.

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