Elemental composition of fine particles: exposure in the general population and influence from different sources
Sammanfattning
The general population is exposed to particulate air pollution from many different local
and regional sources. Examples of local sources are traffic, biomass burning and
resuspended dust, while regional sources are dominated by combustion processes from
heating, traffic and industries. The overall aim of this thesis was to characterise the
personal exposure to trace elements in fine particles, mainly PM2.5 and investigate how the
exposure is related to indoor and outdoor levels. Particulate matter was collected on filters
and analysed for elemental content by X-ray fluorescence (XRF) spectroscopy.
In the general population in Göteborg, personal exposures to Cl, Ca, Ti and Fe were
significantly higher compared with indoor, residential outdoor and urban background
levels. Significant correlations were also found between urban background PM mass and
personal exposure to elements related to both combustion (S, V and Pb) and resuspended
dust (Ti, Fe and Zn), indicating that both sources could be relevant for health effects from
urban background PM. In a community where wood burning for domestic heating is
common, significantly (66–80%) higher personal exposures and indoor levels were found
for K, Ca and Zn compared with a reference group living in the same area, indicating that
these elements could be good markers for wood smoke. In a study in Stockholm
concerning children’s environments (home, school and preschool), higher indoor than
outdoor levels of Ti were found, while long-range-transported (LRT) elements (S, Ni, Br
and Pb) were higher outdoors. A community located 25 km from the city centre had
significantly lower outdoor levels of crustal and traffic-related elements compared with
both the city centre and a suburban area. The levels of Fe and Cu were four times higher in
the central communities. Outdoors, Cu levels were found to correlate well with the traffic
marker NO2, making it a possible elemental marker for traffic-related aerosols in health
studies. Roadside measurements of fine and ultrafine (<100 nm) particles were performed
along a major approach road to Göteborg and the levels of ultrafine particles were
influenced not only by traffic intensity, but also, by wind speed and direction, as well as
boundary layer height. No correlation was found between PM2.5 and ultrafine particles or
traffic, but there was a correlation between PM2.5 and particles sized 100–368 nm. In all
environments studied, the origin of LRT air masses had a strong effect on exposure and
levels of PM elements.
In conclusion, this thesis demonstrates that elemental analysis is a useful method for
better characterising human exposure to fine particles. For several elements, the personal
exposure is often higher than corresponding indoor levels. The origin of LRT elements
affected not only outdoor levels, but also, the personal exposure and indoor levels, and
should be taken into account in time series studies of air pollution and health.
Delarbeten
I. Molnár, P., Janhäll, S., and Hallquist, M., 2002. Roadside measurements of fine and ultrafine particles at a major road north of Gothenburg. Atmospheric Environment 36(25) 4115–4123. II. Molnar, P., Gustafson, P., Johannesson, S., Boman, J., Barregard, L., and Sällsten, G., 2005. Domestic wood burning and PM2.5 trace elements: personal exposures, indoor and outdoor levels. Atmospheric Environment 39(14) 2643–2653. III. Molnár, P., Johannesson, S., Boman, J., Barregård, L., and Sällsten, G., 2006. Personal exposures and indoor, residential outdoor, and urban background levels of fine particle trace elements in the general population. Journal of Environmental Monitoring 8(5) 543–551. IV. Molnár, P., Bellander, T., Sällsten, G., and Boman, J. Indoor and outdoor concentrations of PM2.5 trace elements at homes, preschools and schools in Stockholm, Sweden. Journal of Environmental Monitoring, Accepted.
Examinationsnivå
Doctor of Philosophy (Medicine)
Universitet
Göteborg University. Sahlgrenska Academy
Institution
Inst of Medicine. Dept of Public Health and Community Medicine
E-post
peter.molnar@amm.gu.se
Datum
2007-03-02Författare
Molnár, Peter
Nyckelord
particulate matter
PM2.5
PM1
ultrafine particles
trace elements
personal exposure
X-ray fluorescence (XRF)
indoor levels
air mass back trajectories
long-range transport
domestic wood burning
Publikationstyp
Doctoral thesis
ISBN
978-91-628-7037-9
Språk
eng