The link between human health and the mass of fine particulate matter below 10 µm(PM10) in air is well
documented. Current research suggests that the number, size and shape of particles may be of most concern
and that in the urban atmosphere combustion sources of PM10, especially diesel engine sources, dominate
the line (< 1 µm) and ultra-fine ( <0.1 µm) particles. Despite this, the number, size and shape of particles in
urban air has not been reported to any great extent or detail, and the percentage contribution to the numbers
of particles from different sources is largely unknown. The objectives of this research were to characterise
fine particles with respect to their morphology and thus apportion the sources of particles by number.
Urban aerosol above 1 µm was initially examined to study the fluctuations in PM10 number and make
retrospective analysis of periods of elevated PM10 for source identification in Plymouth, UK. Aerosol was
collected via a Burkard spore trap and examined using light microscopy with image analysis between 16
March 1995 and 31 August 1996, at a background site in Plymouth, UK. Two periods, 19 January-4
February and 10-25 March 1996, identified as UK wide PM10 episodes, were retrospectively studied and
compared with PM10 mass measurements. The mean number count for the whole period was 10.5 x 104 ±
7.9 x 104 particles m ˉ³ The two PM10 episodes had elevated average number concentrations of 13.5 x 104 ±7.6 x 104 particles m ˉ³ for 19 January- 4 February 1996, and 13.0 x 104 ± 9.7 x 104 particles m ˉ³
for 10-25 March 1996. During the periods of elevated PM10 the tapered element oscillating microbalance (TEOM) mass of panicles had a low correlation with the particles less than 5 µm and an increased correlation to the particles greater than 5 µm in size. Outside of these peak periods the PM10 TEOM mass was most closely correlated with the number of particles less than 5 µm in size. This work shows the difference in urban
aerosol during periods of air quality guideline exceedence. These findings agree with literature that an aged
continental aerosol source has a key role in the generation of UK wide PM10 mass exceedances.
Further analysis of the line urban aerosol (< 1 µm) was made using direct sampling of urban aerosol on to
porous carbon films (PCF) developed in this research. The efficiency of collection was low (ea. 5%) but the
samples were representative and enabled transmission electron microscopy (TEM) for sub-micron particle
analysis. Measurement was made of the fractal dimensions and diameter of particles. This was used to
identify any ageing and ultimately the sources of aerosol.
PCF were used in the simultaneous collection of urban roadside and background aerosol, on seven dates
between December 1996 and August 1997 in Plymouth, UK. The average perimeter fractal dimension
(PFD) of aerosol was consistently significantly greater at the roadside than the background (+ 0.02),
indicative of a smoother, aged aerosol at the background site.
The sampling of a variety of combustion engines was made for source identification purposes. The particle
morphology produced from the diesel engines showed great uniformity of particle morphology with varying
speed and load; no consistent significant differences were found. The morphology results were comparable
to other density fractal dimensions and perimeter fractal dimension values found in other studies for diesel.
A natural log relationship between the median particle size and the median PFD was found for the diesel
engine sources but not in petrol samples. This natural log trend was considered as a tentative 'fingerprint'
of diesel engine combustion and was in harmony with literature values of PFD for diesel engine particles.
Using the fractal measures, size and particle classification the bulk of aerosol was identified as from
hydrocarbon combustion sources; ea. 88-92% of the roadside and ea. 77-86% of background. A component
of carbon ceno-spheres were identified contributing ea. 6-12% of both the roadside and background aerosol.
Non-combustion particles increased from ea. 1-4% of the roadside to ea. 7-9% of the background, as did the
proportion of aged combustion particles, from 0-1% of roadside to 2-3% of the background aerosol. A
strong correlation for the median size vs. PFD morphology curve between, the roadside and diesel sources
(0.93 - 0.95) and the background and petrol sources was found (0.95). The roadside aerosol was
significantly different to the petrol source in the l20-220nm size range (p=0.007) and there was a low
correlation of the petrol and the roadside size vs. morphology curve (0.66). This suggests the domination of
Date of Award | 1999 |
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Original language | English |
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Awarding Institution | |
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The Measurement and Characterisation of Aerosol in the Urban Atmosphere (PM10) and an Evaluation ofthe Sources of these Particles by Number
Dye, A. L. (Author). 1999
Student thesis: PhD