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Regional inhaled deposited dose of indoor combustion-generated aerosols in jordanian urban homes

Hussein, Tareq ; Boor, Brandon E. and Löndahl, Jakob LU orcid (2020) In Atmosphere 11(11).
Abstract

Indoor combustion processes associated with cooking, heating, and smoking are a major source of aerosols in Jordanian dwellings. To evaluate human exposure to combustion-generated aerosols in Jordanian indoor environments, regional inhaled deposited dose rates of indoor aerosols (10 nm to 25 µm) were determined for different scenarios for adult occupants. The inhaled deposited dose rate provides an estimate of the number or mass of inhaled aerosol that deposits in each region of the respiratory system per unit time. In general, sub-micron particle number (PN1) dose rates ranged from 109 to 1012 particles/h, fine particle mass (PM2.5) dose rates ranged from 3 to 216 µg/h, and coarse particle... (More)

Indoor combustion processes associated with cooking, heating, and smoking are a major source of aerosols in Jordanian dwellings. To evaluate human exposure to combustion-generated aerosols in Jordanian indoor environments, regional inhaled deposited dose rates of indoor aerosols (10 nm to 25 µm) were determined for different scenarios for adult occupants. The inhaled deposited dose rate provides an estimate of the number or mass of inhaled aerosol that deposits in each region of the respiratory system per unit time. In general, sub-micron particle number (PN1) dose rates ranged from 109 to 1012 particles/h, fine particle mass (PM2.5) dose rates ranged from 3 to 216 µg/h, and coarse particle mass (PM10) dose rates ranged from 30 to 1600 µg/h. Dose rates were found to be dependent on the type and intensity of indoor combustion processes documented in the home. Dose rates were highest during cooking activities using a natural gas stove, heating via natural gas and kerosene, and smoking (shisha/tobacco). The relative fraction of the total dose rate received in the head airways, tracheobronchial, and alveolar regions varied among the documented indoor combustion (and non-combustion) activities. The significant fraction of sub-100 nm particles produced during the indoor combustion processes resulted in high particle number dose rates for the alveolar region. Suggested approaches for reducing indoor aerosol dose rates in Jordanian dwellings include a reduction in the prevalence of indoor combustion sources, use of extraction hoods to remove combustion products, and improved ventilation/filtration in residential buildings.

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author
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type
Contribution to journal
publication status
published
subject
keywords
Aerosol dose rate, Human exposure, Indoor air quality, Lung deposition, Particle number size distributions, Particulate matter (PM), Ultrafine particles
in
Atmosphere
volume
11
issue
11
article number
1150
publisher
MDPI AG
external identifiers
  • scopus:85095965610
ISSN
2073-4433
DOI
10.3390/atmos11111150
language
English
LU publication?
yes
id
fb975527-3094-4d44-aca1-c8ae90bf340b
date added to LUP
2020-11-27 09:26:45
date last changed
2023-11-20 16:07:21
@article{fb975527-3094-4d44-aca1-c8ae90bf340b,
  abstract     = {{<p>Indoor combustion processes associated with cooking, heating, and smoking are a major source of aerosols in Jordanian dwellings. To evaluate human exposure to combustion-generated aerosols in Jordanian indoor environments, regional inhaled deposited dose rates of indoor aerosols (10 nm to 25 µm) were determined for different scenarios for adult occupants. The inhaled deposited dose rate provides an estimate of the number or mass of inhaled aerosol that deposits in each region of the respiratory system per unit time. In general, sub-micron particle number (PN<sub>1</sub>) dose rates ranged from 10<sup>9</sup> to 10<sup>12</sup> particles/h, fine particle mass (PM<sub>2.5</sub>) dose rates ranged from 3 to 216 µg/h, and coarse particle mass (PM<sub>10</sub>) dose rates ranged from 30 to 1600 µg/h. Dose rates were found to be dependent on the type and intensity of indoor combustion processes documented in the home. Dose rates were highest during cooking activities using a natural gas stove, heating via natural gas and kerosene, and smoking (shisha/tobacco). The relative fraction of the total dose rate received in the head airways, tracheobronchial, and alveolar regions varied among the documented indoor combustion (and non-combustion) activities. The significant fraction of sub-100 nm particles produced during the indoor combustion processes resulted in high particle number dose rates for the alveolar region. Suggested approaches for reducing indoor aerosol dose rates in Jordanian dwellings include a reduction in the prevalence of indoor combustion sources, use of extraction hoods to remove combustion products, and improved ventilation/filtration in residential buildings.</p>}},
  author       = {{Hussein, Tareq and Boor, Brandon E. and Löndahl, Jakob}},
  issn         = {{2073-4433}},
  keywords     = {{Aerosol dose rate; Human exposure; Indoor air quality; Lung deposition; Particle number size distributions; Particulate matter (PM); Ultrafine particles}},
  language     = {{eng}},
  number       = {{11}},
  publisher    = {{MDPI AG}},
  series       = {{Atmosphere}},
  title        = {{Regional inhaled deposited dose of indoor combustion-generated aerosols in jordanian urban homes}},
  url          = {{http://dx.doi.org/10.3390/atmos11111150}},
  doi          = {{10.3390/atmos11111150}},
  volume       = {{11}},
  year         = {{2020}},
}