Stochastic Modeling of Short-term Exposure Close to an Air Pollution Source in a Naturally Ventilated Room: an Autocorrelated Random Walk Method

Overview

Journal J Expo Sci Environ Epidemiol

Specialties Environmental Health
Public Health

Date 2013 Sep 26

PMID 24064529

Citations 4

Authors

Kai-Chung Cheng

Viviana Acevedo-Bolton

Ruo-Ting Jiang

Neil E Klepeis

Wayne R Ott

Peter K Kitanidis

Lynn M Hildemann

Affiliations

Soon will be listed here.

Abstract

For an actively emitting source such as cooking or smoking, indoor measurements have shown a strong "proximity effect" within 1 m. The significant increase in both the magnitude and variation of concentration near a source is attributable to transient high peaks that occur sporadically-and these "microplumes" cause great uncertainty in estimating personal exposure. Recent field studies in naturally ventilated rooms show that close-proximity concentrations are approximately lognormally distributed. We use the autocorrelated random walk method to represent the time-varying directionality of indoor emissions, thereby predicting the time series and frequency distributions of concentrations close to an actively emitting point source. The predicted 5-min concentrations show good agreement with measurements from a point source of CO in a naturally ventilated house-the measured and predicted frequency distributions at 0.5- and 1-m distances are similar and approximately lognormal over a concentration range spanning three orders of magnitude. By including the transient peak concentrations, this random airflow modeling method offers a way to more accurately assess acute exposure levels for cases where well-defined airflow patterns in an indoor space are not available.

Citing Articles

COVID-19 Exposure Assessment Tool (CEAT): Exposure quantification based on ventilation, infection prevalence, group characteristics, and behavior.

Schimmoller B, Trovao N, Isbell M, Goel C, Heck B, Archer T Sci Adv. 2022; 8(39):eabq0593.

PMID: 36179034 PMC: 9524836. DOI: 10.1126/sciadv.abq0593.

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Schimmoller B, Trovao N, Isbell M, Goel C, Heck B, Archer T medRxiv. 2022; .

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Modeling turbulent transport of aerosols inside rooms using eddy diffusivity.

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Peak Inhalation Exposure Metrics Used in Occupational Epidemiologic and Exposure Studies.

Virji M, Kurth L Front Public Health. 2021; 8:611693.

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